indoor air monitoring of ethanol and benzene in a …
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INDOOR AIR MONITORING OF ETHANOL AND BENZENE
IN A PILOT WINERY USING ACTIVE SAMPLING
A Thesis
presented to
the Faculty of California Polytechnic State University,
San Luis Obispo
In Partial Fulfillment
of the Requirements for the Degree
Master of Science in Civil and Environmental Engineering
by
Andrew Isao Kaneda
March 2019
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© 2019
Andrew Isao Kaneda
ALL RIGHTS RESERVED
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COMMITTEE MEMBERSHIP
TITLE: Indoor Air Monitoring of Ethanol and
Benzene in a Pilot Winery Using Active
Sampling
AUTHOR:
Andrew Isao Kaneda
DATE SUBMITTED:
March 2019
COMMITTEE CHAIR:
Tracy Thatcher, Ph.D.
Professor of Environmental Engineering
COMMITTEE MEMBER: L. Federico Casassa, Ph.D.
Assistant Professor of Enology
COMMITTEE MEMBER:
Yarrow Nelson, Ph.D.
Professor of Environmental Engineering
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ABSTRACT
Indoor Air Monitoring of Ethanol and Benzene in a Pilot Winery Using Active Sampling
Andrew Isao Kaneda
Acute indoor concentrations of benzene and ethanol were evaluated in the
California Polytechnic State University San Luis Obispo’s pilot winery workroom. Air
samples were collected during four different wine-making activities: fermentation,
fermentation with Brix content testing, post-alcoholic fermentation pressing, and
storage/finishing. Average workroom benzene concentrations ranged from 0.05 to 0.12
mg/m3. Ethanol concentrations in the winery workroom varied with the activity, ranging
from 0.9 to 12 mg/m3. Pressing and fermentation with Brix content testing both led to
higher indoor ethanol concentrations than fermentation without Brix content testing and
storage/finishing.
Tracer gas decay air exchange tests were conducted to determine the air exchange
rate of the winery workroom. A single-space mass-balance model was used to estimate
the air exchange rate for the entire workroom. The calculated air exchange rates were
correlated with wind speeds and wind direction to create a linear model estimating air
exchange rates based on wind speed. These air exchange rates and the indoor
concentrations of ethanol were used with the single-space mass-balance model to
calculate an ethanol emission rate for each activity. Total estimated ethanol emissions for
the four activities were 3.1 lbs. ethanol per 1000 gallons of wine produced.
Key words: volatile organic compound, ethanol, benzene, tracer gas decay, air exchange
rate, indoor air quality, active sampling, thermal desorption, gas chromatography-mass
spectrometry, winery
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ACKNOWLEDGMENTS
I wish to express thanks for the Warren J. Baker Endowment for Excellence in Project-
Based Learning and the Robert D. Koob Endowment for Student Success, providing
funding for my lab analysis supplies.
I would also like to thank SKC Inc. for their generous donations of indoor sampling
pumps.
My special thanks to Dr. Casassa and the Wine and Viticulture Department for facility
access and education on wine-making.
My thanks to Dr. Nelson of the Environmental Engineering Department for sound advice
early in my thesis research.
I would like to express my deep gratitude to Dr. Thatcher of the Environmental
Engineering Department, my thesis advisor, for her patient guidance and enthusiastic
encouragement throughout my project.
Finally, this thesis project would have not be possible without the endless support of my
family and friends throughout.
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TABLE OF CONTENTS
Page
LIST OF TABLES .............................................................................................................. x
LIST OF FIGURES .......................................................................................................... xii
CHAPTER
1. Introduction ..................................................................................................................... 1
2. Background Overview .................................................................................................... 3
2.1 Volatile Organic Compounds in Indoor Air ............................................................. 3
2.1.1 Volatile Organic Compounds’ Effect on Human Health ................................... 4
2.1.2 Volatile Organic Compounds and Indoor Chemical Reactions ......................... 6
2.1.3 Volatile Organic Compounds in Outdoor Air .................................................... 7
2.2 Winery Indoor Air Quality and Outdoor Emissions ............................................... 10
2.3 Previous Research on VOC Monitoring in Wineries .............................................. 10
2.4 Introduction to Sampling Methods and EPA Method TO-17 ................................. 13
2.5 Introduction to the Study of Indoor Air Quality ..................................................... 15
2.5.1 Ventilation and Air Exchange Rate ................................................................. 15
2.5.2 Defining Boundaries and Mass Balance Model ............................................... 17
2.6 VOCs Selected for Study ........................................................................................ 18
2.7 Vinification Process Overview ............................................................................... 19
2.7.1 Harvest ............................................................................................................. 20
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2.7.2 Stem and Crush ................................................................................................ 20
2.7.3 Maceration ....................................................................................................... 21
2.7.4 Fermentation .................................................................................................... 21
2.7.5 Pressing ............................................................................................................ 22
2.7.6 Maturation ........................................................................................................ 22
2.7.7 Clarification ..................................................................................................... 23
2.7.8 Stabilization and Finishing .............................................................................. 23
2.7.9 Bottling ............................................................................................................ 23
2.7.10 Effects of Winery Size on Vinification Process ............................................ 24
2.8. California Wine Production and Air Quality ......................................................... 25
2.8.1 Wine Emissions Compared to Other ROG Sources ........................................ 26
2.9 Winery Emissions Control and Regulations ........................................................... 27
2.9.1 History of Indoor/Outdoor Air Quality Regulation in the United States ......... 28
2.9.2 Winery Emission Regulation ........................................................................... 30
2.9.3 Best Available Control Technologies .............................................................. 31
2.9.4 History of Winery Emission Regulations in California ................................... 33
3. Experimental Methods .................................................................................................. 35
3.1 Tracer Gas Air Exchange Test Theory ................................................................... 35
3.1.2 Tracer Gas Decay Air Exchange Test Method Design .................................... 37
3.1.3 Determination of AER ..................................................................................... 39
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3.2 Sampling Methods .................................................................................................. 40
3.2.1 Sorbent Tube Preparation and Storage ............................................................ 40
3.2.2 Pump Calibration ............................................................................................. 41
3.2.3 Site Sampling Set Up ....................................................................................... 41
3.3 Gas Chromatography-Mass Spectrometry Methods ............................................... 44
4. Results and Discussion ................................................................................................. 47
4.1 Air Exchange Rate Determination .......................................................................... 47
4.2 VOC Calibration Curves for GC-MS ..................................................................... 49
4.2.1 Absence of Calibration Curves for Ethylbenzene, Toluene, and Xylene ........ 51
4.3 Indoor Concentrations of Ethanol and Benzene Inside of Winery Workroom ....... 52
4.3.1 Analysis of Sampling Quality Assurance and Quality Control ....................... 56
4.3.2 Ethanol Concentration Variation Between Samples, Pumps, and Activity ..... 57
4.3.3 Indoor Air Concentration Compliance with OSHA Regulations .................... 58
4.4 Calculated Emissions for Each Workroom Activity ............................................... 59
4.5 Issues Encountered During Study ........................................................................... 61
5. Conclusion .................................................................................................................... 62
5.1 Future Areas of Research ........................................................................................ 63
BIBLIOGRAPHY ............................................................................................................. 65
APPENDICES
A. CARB 2016 ROG Emissions Inventory ...................................................................... 74
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B. USDA Grape Crush by Type and Activity for 2017 Wine Crush Season ................... 77
C. Measured GC Abundance and Calculated Indoor Concentrations of Ethanol and
Benzene ................................................................................................................. 82
D. Ethanol and Benzene GCMS Calibration Points ......................................................... 86
E. AER Calculation Data .................................................................................................. 87
x
LIST OF TABLES
Table Page
1. OSHA and Cal/OSHA regulatory limits ....................................................................... 10
2. Review of average ethanol and BTEX concentrations from different indoor
environments ......................................................................................................... 12
3. Emission rates of select VOC compounds from emission model (Sarwar, Corsia, &
Kimura, 2002) ....................................................................................................... 13
4. Select Winery Classifications ....................................................................................... 24
5. Calculated Ethanol Emissions from 2017 California Wine Season.............................. 26
6. Comparison of Select Source Emissions of VOCs ....................................................... 27
7. VOC Compound Standards........................................................................................... 45
8. Sorbent Tube Desorption Parameters ........................................................................... 45
9. Focusing Trap Desorption Parameters .......................................................................... 46
10. GC-MS Parameters ..................................................................................................... 46
11. Calculated AERs from Tracer Gas Decay Tests ......................................................... 47
12. Calculated AERs and Wind Data ................................................................................ 47
13. VOC Sampling Date and Estimated AER .................................................................. 49
14. Sampling Date and Activity Type............................................................................... 52
15. Average Workroom Benzene Concentrations by Sampling Day ............................... 55
16. Average Workroom Ethanol Concentrations by Activity ........................................... 55
17. Ethanol and Benzene Concentration Equivalent Measurements on Method Blanks
(mg/m3) ................................................................................................................. 57
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18. Fermentation w/ Brix Content Test Activity Pump 3 Ethanol Concentrations
by Sample Number ............................................................................................... 57
19. Fermentation w/ Brix Content Test Activity Ethanol Concentrations by Pump
Number ................................................................................................................. 58
20. Comparison of OSHA and CAL/OSHA Exposure Limits to Calculated
Concentrations ...................................................................................................... 58
21. Ethanol Generation Values by Activity ...................................................................... 60
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LIST OF FIGURES
Figure Page
1. Summary of photochemical smog formation .................................................................. 9
2. Basic vinification flowchart for red and white wines. .................................................. 20
3. Basic flow diagram of a wet scrubber ........................................................................... 32
4. Basic flow diagram of a chiller condenser .................................................................... 32
5. Basic layout of the winery workroom showing locations of Fluke 975 meters
measuring CO2 Concentrations ............................................................................. 39
6. Tracer gas decay modeling for data collected from 9-7-2018 plotted using
an AER of 10.2 hr-1 ............................................................................................... 40
7. Pump locations in winery workroom for Session 2 on November 16, 2018;
Session 3 on November 19, 2018; Session 4 on November 30, 2018. Pump 4
was not operational during Session 1.................................................................... 43
8. Site map of winery workroom and surrounding area (Google, n.d.) ............................ 44
9. Air exchange rate (AER) vs. wind speed model for winery workroom ....................... 48
10. Benzene calibration curve ........................................................................................... 50
11. Upper range ethanol calibration curve ........................................................................ 50
12. Lower range ethanol calibration curve ....................................................................... 51
13. GC-MS chromatograph from sample AS07 collected on November 19, 2018 .......... 53
14. Benzene concentration by pump location and date..................................................... 54
15. Ethanol concentration by pump location and activity type ......................................... 54
16. Typical Fermentation Locks (Pressure Cooker Outlet, 2019) .................................... 56
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1. Introduction
This thesis project focused on two objectives:
1. Evaluate the indoor concentrations of ethanol and benzene in the Cal Poly pilot
winery using active sampling.
2. Calculate ethanol emission rates within the winery workroom during the selected
wine making activities.
Preliminary tracer gas decay air exchange tests were performed to determine the
air exchange rate of the winery workroom. Then, the air exchange rates were used with
wind data to create a model estimating the linear relationship between the workroom’s air
exchange rate and wind speed. A single-space mass-balance model of the winery
workroom was used to estimate ethanol emissions using indoor ethanol concentrations.
Pilot winery workroom air samples were collected during four activities:
fermentation with Brix content testing, fermentation without Brix content testing,
pressing post-alcoholic fermentation, and finished wine storage. Air samples collected
from each activity were analyzed using thermal desorption gas chromatography-mass
spectrometry. Using measured ethanol concentrations and modeled air exchange rates,
ethanol emission rates for each activity were calculated.
This study’s intended purpose is to be a stepping stone for further research for
indoor air quality monitoring and VOC emission monitoring for wineries. The findings in
this study should not be interpreted as scalable for wineries larger than the Cal Poly pilot
winery, as processes between small and large wineries vary. However, ethanol and other
winery-emissions should be monitored at all sizes of production to determine how
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production methods influence emission rates and to ensure the safety of the workers and
the environment.
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2. Background Overview
To properly frame the context of this study, the following five essential questions
will be addressed in this background:
1. What are volatile organic compounds, and how do they affect human health and
indoor and outdoor air quality?
2. Why are winery indoor air quality and VOC emissions relevant to the
environmental and anthropogenic health of California?
3. What scientific investigations have been conducted on winery indoor air quality
and VOC emissions?
4. How are volatile organic compounds measured and quantified in environmental
sampling?
5. What are the foundational concepts of the study of indoor air quality, and how do
they relate to this study?
2.1 Volatile Organic Compounds in Indoor Air
Volatile organic compounds (VOCs) are a broad spectrum of carbon-based
chemicals that are gaseous at room temperature (LBNL Indoor Environmental Group,
2018) (California Air Resources Board, 2009). Sources of indoor VOC emissions include
paints, cleaning supplies, building materials, indoor smoking, cooking fuels, cosmetics,
printers, carpets, and air fresheners (Wolkoff, Clausen, Jensen, Nielsen, & Wilkins, 1997)
(Franco, Chairez, & Paznvak, 2012) (El-Hashemy & Ali, 2018). The label of VOC is
broad, as chemicals that fall under this label come in a variety of structures. Alkanes,
aromatics, terpenes, and halocarbons are the most prevalent in indoor air and are of
research interest for their detrimental impact on human health (Zabiegala, Przyk, &
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Przyjazny, 2000) (Sarwar, Corsia, & Kimura, 2002) (Khanchi, Hebbern, Zhu, & Cakmak,
2015). In the atmosphere, VOC emissions contribute to the greenhouse gas effect and
play a critical role in the formation of photochemical smog.
2.1.1 Volatile Organic Compounds’ Effect on Human Health
The effect of VOCs on human health is a significant concern in indoor air quality.
As previously stated, there are many sources indoors and outdoors that emit VOCs,
making it important to understand how these chemicals affect human health. Previous
studies have been conducted to determine if there are correlations between VOC
exposure and adverse symptoms. For example, Aziz Khanchi et al. examined the
relationship between indoor and outdoor VOC concentrations and cancer/non-cancer risk
for residents in Windsor, Canada. This study concluded that VOC concentrations alone
should not be relied on for determining cancer/non-cancer risk in people but should be
taken into consideration for a more comprehensive evaluation (Khanchi, Hebbern, Zhu,
& Cakmak, 2015). Another study by J.E. Colman Lerner et al. sought to characterize
health risk in occupational settings in Buenos Aires, Argentina. The study determined
that the use of VOC control technologies resulted in decreased indoor VOC
concentrations, and suggested VOC’s role in increased cancer risk (Colman Lerner,
Sanchez, Sambeth, & Porta, 2012).
Exposure is a critical health and safety concept. For this study, exposure will be
defined as the physical contact between a person and the constituent of concern via skin
or inhalation for a duration of time (Thatcher, et al., 2001). The correlation between
adverse health effects and VOCs involves both exposure and toxicity: the more a subject
is exposed to a VOC, the greater the likelihood of detrimental health effects due to its
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toxicity. VOCs such as benzene and styrene are commonly analyzed and sampled for, as
they produce adverse effects on human health (Sundell, 2004) (Weschler, 2004) (Zhao,
Cheng, Lin, & Cheng, 2016).
Adverse health effects have been categorized by OSHA into two categories: acute
and chronic effects. Acute effects are those that occur rapidly due to short-term exposure,
while chronic effects can appear after extended exposure (Occupational Safety and
Health Administration, 2018). Examples of acute effects from VOC exposure include
throat irritation, runny or burning nose, and headaches; chronic effects of long-term VOC
exposure include increased cancer risk, decreased lung function, and increased
respiratory morbidity (Colman Lerner, Sanchez, Sambeth, & Porta, 2012) (Wolkoff,
Clausen, Jensen, Nielsen, & Wilkins, 1997) (Ravsoni, et al., 2017) (Zabiegala, Przyk, &
Przyjazny, 2000). The severity of these effects is correlated to several factors, including
the concentration of VOCs, length of exposure, and personal factors of the individual
exposed.
While there is significant evidence suggesting exposure to VOCs is hazardous, the
concentration of a single VOC or a sum concentration of all VOCs is not a direct measure
of the safety of an indoor or outdoor environment. VOC concentrations must be
considered with other factors such as relative toxicity of the compounds, temperature,
relative humidity, and other environmental conditions. The study of VOC emissions is a
critical aspect of assessing air quality, as it can affect humans in ways other than direct
exposure (Sundell, 2004) (Wolkoff, Clausen, Jensen, Nielsen, & Wilkins, 1997)
(Khanchi, Hebbern, Zhu, & Cakmak, 2015).
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Benzene and ethanol were the VOCs analyzed in this study. Benzene is a VOC
that is toxic to humans, damaging the immune system and bone marrow (Center for
Disease Control and Prevention, 2018). However, it is not the by-product of wine making
specifically: it is a VOC by-product of engine combustion. The pilot winery was located
at the cross-roads of two heavy-traffic roads into the university and surrounded by four
agricultural fields that were heavily used during sampling, raising concern for exposure
of benzene in the winery workroom. Acute airborne exposure to ethanol causes similar
health effects as ethanol ingestion, including eye irritation, headaches, vomiting, and
unconsciousness (New Jersey Department of Public Health, 2016).
2.1.2 Volatile Organic Compounds and Indoor Chemical Reactions
Monitoring and control of VOCs (benzene, ethanol, etc.) are critical aspects of
indoor health, but recent research suggests that there may be more to consider. In a
review article, P. Wolkoff suggests that low concentrations of primary VOCs may not
necessarily indicate low emission rates since indoor reactions may convert emitted VOCs
to harmful secondary pollutants (Wolkoff, Clausen, Jensen, Nielsen, & Wilkins, 1997).
Indoor environments are highly favorable for chemical reactions, particularly reactions
involving ozone and VOCs (Weschler, 2004). Due to ozone’s atmospheric prevalence
and the generation of VOCs from natural and anthropogenic sources, these reactions are
common in indoor environments (Sarwar, Corsia, & Kimura, 2002). The increased
surface-to-volume ratio in an enclosed environment promotes O3 and VOC interaction,
resulting in the formation of hydroxyl (OH) radicals. OH radicals are potent oxidizers and
will react with other VOCs to form alkyl and peroxy radicals (Wolkoff, Clausen, Jensen,
Nielsen, & Wilkins, 1997) (Slominska, Konieczka, & Maniesnik, 2014). These secondary
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radicals have been shown react with the primary emitted VOCs and other constituents in
the building via similar surface reactions, perpetuating the cycle of VOCs and ozone
producing hydroxyl radicals. The radicals can cause physical irritation to building
occupants through oxidation reactions with other airborne constituents, as well as
interacting directly in the membranes of the eyes and nose (Weschler, 2004) (Sundell,
2004) (Wolkoff, Clausen, Jensen, Nielsen, & Wilkins, 1997).
Indoor chemical reactions between ozone and VOCs occur within minutes
(Weschler, 2004). Thus, sampling strategies should evaluate the meaning behind certain
VOC concentrations. It may be the case that low concentrations of primary reactants are
measured, but products of these reactions could be increasing to an equilibrium state in
the room. The idea of “the lamp-post effect” was asserted by J. Sundell. At night, it is
difficult to see what is around if it isn’t illuminated by a lamp-post; similarly, scientists
can only focus on what they are able to measure (i.e. under the “lamp-post”). Sundell
suggests that although there is no direct association between measured VOC
concentrations and health effects, the measurements aren’t without meaning. Researching
efforts should be directed to further understand possible correlations between IAQ and
human health by evaluating VOC reactants, products, and the risk they pose to the
environment (Sundell, 2004).
2.1.3 Volatile Organic Compounds in Outdoor Air
The formation of photochemical smog is the result of a complex series of
reactions between nitrous oxides, ozone, and emitted VOCs (Slominska, Konieczka, &
Maniesnik, 2014) (Figure 1). VOC emission sources include traffic emissions, gasoline
evaporation, industrial emissions, and solvent usage (near-road schools, isomeric
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analysis, fate). Additionally, indoor chemical reactions resulting in the formation of alkyl,
peroxy, and hydroxyl radicals can be ventilated to the outdoor air and contribute to the
formation tropospheric ozone (Slominska, Konieczka, & Maniesnik, 2014). Nitrogen
dioxide is energized by solar irradiation, triggering a reaction with existing oxygen in the
atmosphere to form ozone. This ozone is part of photochemical smog’s composition, but
also plays a role in the radicalization of VOCs in the atmosphere (Shan, et al., 2007).
Once the VOCs are oxidized, they will react with nitrogen dioxide in the atmosphere to
form peroxyacyl nitrates (PAN) and aldehydes, another component of photochemical
smog. Nitric acid is another major component of photochemical smog, formed by the
reaction between water vapor in the air and nitrogen dioxide (Miller & Hackett, 2011).
The wine making season is from early August to late October. This timeframe has the
hottest and sunniest weather California experiences: sunlight and heat are two major
driving forces for the formation of photochemical smog (California Air Resources Board
Ozone, 2016). Thus, VOC emissions from wineries have the potential to increase the
formation of photochemical during the wine making season.
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For an individual building, the emissions of a given VOC are dependent on the
equipment and processes inside. Office equipment such as printers, air purifiers, and
paints/solvents contribute to the VOC profile within a building (Caselli, de Gennaro,
Saracino, & Tutino, 2009). To maintain safe concentrations, OSHA has set maximum
occupational exposure limits (OEL) for key VOCs (Table 1) (Occupational Safety and
Health Administration, 2018) (Occupational Safety and Health Administration, 2018).
While the atmospheric profile does not consist of only indoor sources, the emission of
VOCs and their derivatives from multiple building sources increases the formation of
Figure 1. Summary of photochemical smog formation
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photochemical smog when combined with outdoor emissions (e.g. cars and industrial
processes).
Substance OSHA 8-hour TWA (ppm) Cal/OSHA 8-hour TWA (ppm)
Benzene 10 1
Ethyl alcohol 1000 1000
2.2 Winery Indoor Air Quality and Outdoor Emissions
California is the largest producer of wine in the United States, responsible for
81% of the country’s production in 2018 (Wine Institute, 2017). Approximately 4 million
tons of grapes were grown and crushed in 2018, with 241 million cases sold in the United
States (Wine Institute, 2017). This large-scale production of wine has attracted the
attention of air quality regulatory agencies such as the USEPA, the California Air
Resources Board (CARB), and local bodies such as the San Joaquin Air Pollution Control
District and the Santa Barbara Air Pollution Control District (APCD). The San Joaquin
and Santa Barbara APCDs are responsible for regulating their respective counties that
collectively contribute 70% of California’s wine production (Wine Institute, 2019). The
largest emissions from wine production are ethanol and carbon dioxide (CO2) (Midwest
Research Institute, 1995). Ethanol is a volatile organic compound (VOC) that contributes
to the formation of photochemical smog when emitted into the atmosphere and is
monitored by the APCDs. Indoor concentrations are regulated by OSHA.
2.3 Previous Research on VOC Monitoring in Wineries
The presence of hazardous VOCs in wine-production facilities is an understudied
aspect of indoor air quality. Historically, the main concerns for winery facilities have
been CO2 and ethanol, as both are generated in large quantities during fermentation and
Table 1. OSHA and Cal/OSHA regulatory limits
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crush (Midwest Research Institute, 1995). However, advances in occupational health
monitoring and increased regulations call for a more comprehensive look at the
composition of indoor air quality at wineries. A study conducted by Daniel Sanjuan-
Herrarez et al. evaluated hazardous VOC concentrations in a Spanish winery, using
diffusive sampling to measure long-term exposure (Sanjuan-Herraez, de la Osa, Pastor, &
de la Guardia, 2014). These concentrations were compared to those outlined by the
registration, evaluation, authorization, and restriction of chemical substances (REACH)
European standards and were determined to meet the REACH standards (Table 2).
Because of the minimal amount of research conducted on indoor air quality at
wineries, other indoor environments and conditions were reviewed for VOC
concentrations as a source of comparison. Three different settings were reviewed:
building construction, near-road schools, and an indoor VOC concentration and VOC
emission model for a generic indoor space.
Building construction is a process that uses many VOC-emitting products. A
study conducted by Weihui Liang et al. determined that paints, flooring, and wall
formation are all contributors to VOC emissions during apartment building construction
(Table 2) (Liang, Wang, Yang, & Yang, 2014). A study by Zabiegala et al. was
conducted to determine ambient indoor concentrations after the construction process of
an apartment, rather than during construction (Zabiegala, Przyk, & Przyjazny, 2000). P.
Wolkoff et al. determined that building materials will continually emit VOCs that make
up the material’s composition, causing unwanted emissions that can be potentially
harmful to building occupants (Wolkoff, 1990).
12
The winery workroom in this study is located near a busy road in the university,
seeing constant commuting traffic throughout the day. A study conducted by Amit U.
Raysoni et al. analyzed hazardous VOC concentrations in four elementary schools near
busy roads in El Paso, Texas. The study concluded that there was a significant correlation
between outdoor BTEX concentrations and heavy traffic, as well as a corresponding
increase for indoor BTEX concentrations (Table 2) (Ravsoni, et al., 2017).
Study* Ethanol
(µg/m3)
Benzene
(µg/m3) Toluene
(µg /m3) Ethylbenzene
(µg /m3)
m-,o-,p-
Xylene
(µg /m3) Air monitoring in
wineries - 0.1 0.3 0.1 0.1
Interior
Construction - 79.2 361.1 127.6 41.5
Hydroxyl - Sawar 188.4 0.4 1.1 0.2 0.2 Evaluation of
IAQ - 0.5 53.7 95.4 339.2
Near Road
Schools - 0.7 2.9 0.6 0.9
*References in descending order: (Sanjuan-Herraez, de la Osa, Pastor, & de la
Guardia, 2014) (Liang, Wang, Yang, & Yang, 2014) (Sarwar, Corsia, & Kimura, 2002)
(Zabiegala, Przyk, & Przyjazny, 2000) (Ravsoni, et al., 2017).
Golam Sarwar et al. estimated the indoor concentration of hydroxyl (OH) radicals
with the use of an indoor air quality model that utilized the SAPRC-99 atmospheric
chemistry model to replicate indoor reactions (Sarwar, Corsia, & Kimura, 2002). This
model calculated the emission rate of select VOCs with an air exchange rate of 0.53 hr-1
(Table 3).
Table 2. Review of average ethanol and BTEX concentrations from different indoor
environments
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Compound Emission Rate (mg/min)
Ethanol 0.555
Benzene 0.035
Toluene 0.133
Ethylbenzene 0.026
Xylene 0.022
2.4 Introduction to Sampling Methods and EPA Method TO-17
Two sampling methods were considered for this study: active and passive
sampling. Active sampling involves the use of a pump to actively collect a volume of air,
while passive sampling utilizes diffusion to sorb contaminants onto a media. This study
focused on the short-term exposure of wine crush participants to VOCs during the wine
crush and fermentation processes. As previously mentioned in Section 2.1.1, acute effects
occur due to short-term exposure. Thus, an active sampling strategy was employed to
determine short-term exposure of the participants to VOCs throughout the wine crush.
Active sampling is often used for acute exposure periods because of its ability to sample
for contaminants in a shorter amount of time than passive sampling, which is utilized to
determine an average concentration over a longer period (Goodman, et al., 2017).
Additionally, the active sampling strategy avoids burdening the winery workroom with
equipment for an extended period, as the crush and fermentation season lasts up to 90
days (Midwest Research Institute, 1995) (Storm, 1997). In addition, the various stages
and activities in the wine making process have different emission profiles which requires
short term sampling to determine appropriate activity related emission rates. The
sampling strategy employed also allowed for sample collection representative of a long-
term mixture of different operation and weather conditions.
Table 3. Emission rates of select VOC compounds from emission model (Sarwar, Corsia, &
Kimura, 2002)
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The 1999 EPA Compendium Method TO-17: Determination of Volatile Organic
Compounds in Ambient Air Using Active Sampling onto Sorbent Tubes guidelines were
used for developing the sampling and analysis strategies of VOCs in the winery
workroom air. TO-17 calls for the use of sorbent tubes with analysis using gas
chromatography via thermal desorption for gas chromatography-mass spectrometry (GC-
MS) analysis (Center for Environmental Research Information Office of Research and
Development, 1999). Thermal desorption is an ideal choice for GC-MS analysis when
coupled with sorbent tubes, proving to be effective and resource-efficient. The process of
thermal desorption coupled with GC-MS creates few waste products and can reuse most
of its supplies. There are no solvents or reagents used during thermal desorption,
decreasing the likelihood of analysis interference in the gas chromatograph (Sanjuan-
Herraez, de la Osa, Pastor, & de la Guardia, 2014) (Zhang, Zhao, Xu, Wang, & Miao,
2010). The results of analysis using thermal desorption are comparable to solid-phase
micro-extraction (SPME), and thermal desorption aids analysis by removing unnecessary
tails in the results (Zhang, Zhao, Xu, Wang, & Miao, 2010). Thermal desorption also
allows for the reuse of the sorbent tubes: each tube is decontaminated of analytes, also
known as “conditioned,” each time it is inserted into the thermal desorber for GC-MS
analysis. This is convenient if resources for sampling materials are limited, as sampling
runs can be completed as soon as the initial tubes are analyzed. The TO-17 methodology
was ideal for this study: guidelines for use of active sampling along with sorbent tubes
helped ensure the quality of the data collected. Concentrations for all measured
constituents were compared to OSHA and Cal/OSHA regulatory limits to ensure
compliance (Occupational Safety and Health Administration, 2018).
15
2.5 Introduction to the Study of Indoor Air Quality
Indoor air quality is a field of research that is extremely important as humans now
spend as much as 90% of their day inside (Sundell, 2004). The well-being of people is
affected by the composition of the indoor air (Sanjuan-Herraez, de la Osa, Pastor, & de la
Guardia, 2014) (Sundell, 2004). The study of indoor air quality aims to understand the
factors that make an indoor environment a comfortable and healthy place for individuals
to work or live.
2.5.1 Ventilation and Air Exchange Rate
To maintain a thermally controlled environment, building designers and engineers
can manipulate the indoor climate through ventilation. Ventilation systems rely on
mechanical ventilation to control factors such as temperature and indoor concentrations
of anthropogenic and natural constituents. Mechanical ventilation consists of a system of
exhaust fans to move air from the outside-in and from inside-out via ductwork
infrastructure; it is often accompanied by additional mechanisms like filters and
condensate coils to help facilitate the comfortable environment desired by the inhabitants
(Thatcher, et al., 2001).
Conversely, natural ventilation is the flow of air through open windows, doors, or
any other intentional opening to the outdoor environment. Natural ventilation is
predominantly determined by two factors: the size of the openings and the outdoor
weather conditions. Unlike mechanical ventilation, natural ventilation has no controls
over what air enters the building: this poses a potential threat to the inhabitants if
dangerous levels of chemicals or particulate matter are close to the building (Thatcher, et
al., 2001).
16
A third factor affecting the air exchange rate is infiltration. Infiltration is the flow
of air through small cracks and openings common in all buildings. Unlike natural
ventilation, it is not designed into the construction of the building, but rather a result of it.
Infiltration air flow rates are determined by the pressure differential between the interior
and exterior sides of the opening (Thatcher, et al., 2001).
The combination of mechanical ventilation, natural ventilation, and infiltration in
concert is quantified as the air exchange rate (AER). Measured in units of hour-1, AERs
are a measure of the number of times the volume of air in a space is exchanged with
outdoor air in one hour. AERs are critical in determining the mass-balance of chemicals
and airborne constituents for an indoor environment (Thatcher, et al., 2001) (El-Hashemy
& Ali, 2018). AERs are a versatile measure of a building’s ventilation, as building size
does not affect the units of this measurement.
Air exchange tests are utilized to approximate the AER of a space and are a
critical tool for HVAC engineers to evaluate indoor comfort. Recommended air exchange
guidelines are set by the American Society of Heating, Refrigeration, and Air
Conditioning Engineers (ASHRAE), depending on the nature of the indoor space.
ASHRAE Standard 62 is the primary guideline for designing ventilation systems for
commercial and residential buildings and is published to aid HVAC engineers create a
safe and comfortable space for the building inhabitants (Storm, 1997).
AERs are often readily available for recently built buildings, with design
parameters set into an automated control system. However, older buildings without an
automated HVAC system require further testing to determine an AER.
17
2.5.2 Defining Boundaries and Mass Balance Model
An important concept in the study of indoor air quality is that of the building
shell: the building shell is the defined boundary line between the interior of the building
and the outdoor environment that the building is located in. To understand the make-up
of the indoor air, the building shell is critical for creating a mass-balance model.
Once the boundary is established, the make-up of the inside air can be estimated
through a mass-balance equation. By including various terms to describe the composition
of the indoor air, this change is described as:
∆Co ∗ V
∆t= OutdoorSourceEntry − VentilatedOutside − MassRemoval
+ IndoorMassGeneration
C0 = compound concentration
V = volume of room
t = elapsed time
The outdoor source entry term describes outdoor contaminants that are introduced
into the indoor air via ventilation or infiltration. Ventilation rates will affect the
concentration of the constituent being expelled. Mass removal is the combination of
indoor chemical reactions and physical capture technologies, both of which vary based on
the agent of concern and indoor concentrations. Filters and scrubbers are a common way
to physically capture particulate matter and compounds such as ethanol (Santa Barbara
Air Pollution Control District, 2018). Generally, indoor chemical reaction rates will differ
based on site conditions and quantities of the reactants, making estimates difficult to
accurately estimate (Sarwar, Corsia, & Kimura, 2002) (Wolkoff, Clausen, Jensen,
Nielsen, & Wilkins, 1997). To determine the profile of the indoor air quality, mass
(2.1)
18
generation sources are important to identify and quantify. Indoor air pollution is
generated by many sources, which vary between different indoor spaces within a building
(Burge, 2004).
2.6 VOCs Selected for Study
This study focused on two VOCs: ethanol and benzene. Ethanol has been
identified as the most dominant VOC in winery air, due to its emission from fermentation
(Midwest Research Institute, 1995). Ethanol has been approved by the EPA as an
environmentally-friendly alternative for fuel and a substitute for many household
chemicals (United States Environmental Protection Agency, 2018). But recently, there
has been controversy over the impact that ethanol emissions have on the environment. An
EPA report released in late June 2018 emphasized that there have been negative
environmental impacts associated with the increase of ethanol emissions during the bio-
fuel manufacturing process, including contribution to the greenhouse gas inventory as
well as formation of tropospheric ozone (United States Environmental Protection
Agency, 2018) (Yassaa, Brancaleoni, Frattoni, & Ciccioli, 2006) (Semadeni, 1994).
Ethanol has also been a regulated VOC in California since 2005, particularly in counties
that have large-scale wine production (San Joaquin Air Pollution Control District, 2005).
Benzene is part of a group of VOCs referred to as BTEX, which is comprised of
benzene, toluene, ethylbenzene, and xylene (El-Hashemy & Ali, 2018) (Sanjuan-
Herraez, de la Osa, Pastor, & de la Guardia, 2014) (Slominska, Konieczka, & Maniesnik,
2014) (Chen, Zhou, & Qi, 2008). Acute effects of short-term exposure to BTEX are
headaches, dizziness, and mental confusion. Long-term exposure to BTEX has been
linked with increased cancer risk as well as disruption to the endocrine system (Khanchi,
19
Hebbern, Zhu, & Cakmak, 2015) (El-Hashemy & Ali, 2018) (Ravsoni, et al., 2017).
BTEX is a critical group of aromatic compounds to sample for because of its increasing
prevalence in the outdoor and indoor air. Common outdoor sources of BTEX include
vehicle emissions, industrial emissions, and gasoline evaporation (Goodman, et al., 2017)
(Slominska, Konieczka, & Maniesnik, 2014) (Ravsoni, et al., 2017). Air fresheners,
various cleaning products, and adhesives have been cited as some of the indoor sources
of BTEX (El-Hashemy & Ali, 2018) (Khanchi, Hebbern, Zhu, & Cakmak, 2015) (Bari,
Kindzierski, Wheeler, Heroux, & Wallace, 2015).
Only ethanol and CO2 are produced directly from vinification: benzene is not a
byproduct of wine-making. However, benzene is commonly found in air that experiences
high vehicle activity (Ravsoni, et al., 2017) (Sanjuan-Herraez, de la Osa, Pastor, & de la
Guardia, 2014) (Slominska, Konieczka, & Maniesnik, 2014). Because the winery
workroom in this study is located near a busy road, popular parking lot, and agricultural
fields, engine combustion emissions have been identified as a potential hazard to the
indoor air of the winery workroom. Thus, benzene was chosen as the indicator compound
for engine combustion emissions inside of the winery workroom.
2.7 Vinification Process Overview
Wine is an alcoholic beverage consisting of fermented sugars from fruit juice
most commonly made with grapes. Wine production, also known as vinification, is a
multi-stepped process (Figure 2) (Midwest Research Institute, 1995). This section will
focus on:
1. Identifying critical steps in the wine-making process.
2. Determining an estimate of California wineries’ contribution to VOC emissions.
20
2.7.1 Harvest
Harvest is the process of collecting grapes from their vines and transporting them
for stemming and crushing. Because of the grape’s delicate skin and body, sulfite
compounds are used to prevent the growth of mold or bacteria on the grapes during
transportation between the fields and the processing facility (Midwest Research Institute,
1995). The harvest season is from August to October (Robinson, 2006).
2.7.2 Stem and Crush
Stemming and crushing grapes immediately after harvest is commonly practiced
to prevent the growth of bacteria and mold. Stemming involves the removal of leaves,
stems, and other residual plant matter from the grape bodies. During crush, the grape’s
juices are extracted from the grape body via physical processes like pressing and
centrifugal forces (Storm, 1997). Typically, both the stemming and crushing process are
handled in the same step utilizing a crusher-stemmer (Storm, 1997) (Midwest Research
Institute, 1995).
Figure 2. Basic vinification flowchart for red and white wines.
21
2.7.3 Maceration
Maceration is the biological and physical degradation of grape solids, yielding a
mixture of solid and liquid grape matter called “must.” Red and white wines have
different kinds of must: red wine must includes all solid and liquid grape matter, while
white wine must only consists of the juice that is separated from the solids. Maceration
time and treatment will vary depending on the type of wine to be produced and the flavor
profile that is being pursued (Midwest Research Institute, 1995).
2.7.4 Fermentation
There are two types of fermentation: alcoholic fermentation and malolactic
fermentation. Malolactic fermentation is a secondary fermentation used to reduce the
acidity of the fermented juice. In alcoholic fermentation, sugars such as fructose and
glucose are processed by yeast cultures to form C2H5OH (ethanol) and CO2 (Walker &
Stewart, 2016).
C6H12O6 → 2C2H5OH + 2CO2 ( 2.2)
Alcoholic fermentation is initiated with the addition of yeast cultures into the
must. Common fermentation vessels include wooden, plastic, or metal barrels and tanks.
Fermentation is an exothermic process, requiring constant temperature monitoring and
control as yeast culture death in the batch will completely disrupt the fermentation
process. Fermentation monitoring also includes the measurement of Brix content (°B):
one-degree Brix is equal to 1 gram of sucrose per 100 grams of solution. Initial Brix
content is a key parameter because fermentation stops once the sugar content of the
fermenting juice is zero. As with maceration, red and white wines fermentation
techniques differ. Red wines are fermented at higher temperatures than white wines, 25°-
22
28°C and 8-15°C, respectively. Brix content also varies between reds and whites, with
reds fermenting at 23 °B initial and whites at 20 °B initial (Storm, 1997) (Midwest
Research Institute, 1995).
According to G.M. Walker et al., the stoichiometric conversion of glucose to
ethanol is 180 grams of glucose to 92 grams of ethanol and 88 grams of CO2. In common
practice, G.M. Walker estimates that yields are at most 90% of the theoretical yield, as
some carbon that would be released as CO2 is instead consumed to produce more yeast
biomass (Walker & Stewart, 2016). As glucose reserves in the must and juices decreases
throughout fermentation, ethanol and CO2 production also decreases.
2.7.5 Pressing
During fermentation, additional juice from the must is extracted during the
pressing stage. There are typically two phases to this step. First, the must rests so that its
juices can be collected passively. Afterward, the remaining juices in the must are
extracted through active pressing. This pressing can be performed by rollers or by gas
compression against a perforated screen (Walker & Stewart, 2016) (Midwest Research
Institute, 1995).
2.7.6 Maturation
Prior to bottling, wine profiles are adjusted through a series of changes to their
major characteristics: acidity, sweetness, alcohol content, and color adjustment. In this
step, wines can be blended with other varieties to change the flavor profile.
Physicochemical or biological processes are also applied during maturation to manage
acidity via precipitation of VOCs such as tartaric acid (Midwest Research Institute,
1995).
23
2.7.7 Clarification
Clarification is the process of removing sediment from the wine. Wine sediment
is the combination of yeast and bacteria cells, grape matter, and precipitated matter from
the maturation step. This is a critical step, as sediment will spoil the wine if it is not
completely removed during the clarification phase. Clarification can be performed by
decantation between multiple vessels or by centrifugal force (Midwest Research Institute,
1995).
2.7.8 Stabilization and Finishing
Prior to the bottling phase, the producer will prevent sediment accumulation and
taste change through stabilization. Common stabilization techniques include clarification
and filtration, as well as aging. Aging allows for organic compounds in the wine to break
down, altering the aroma, color, and taste of the wine. Finishing is often associated with
stabilization, but similar to clarification in that chemical agents are added to further
precipitate sediment from the wine. The precipitated sediment will be filtered from the
wine before bottling in a final clarification/filtration step (Midwest Research Institute,
1995).
2.7.9 Bottling
Excessive oxidation in wine can ruin the aroma and taste, so extra precautions are
taken during bottling to minimize contact between the finished wine and the atmosphere.
Disinfectants such as sulfur dioxide and fluid transfer via siphon or vacuum pump can
help minimize oxidation potential (Midwest Research Institute, 1995).
24
2.7.10 Effects of Winery Size on Vinification Process
The Santa Barbara APCD identified three general classifications of wineries:
boutique/small wineries, industrial sized wineries, and wine refineries (Goldman, 2018).
This scale is based on three determining factors: size of fermentation tanks, VOC
emissions, and greenhouse gas emissions. The boutique/small wineries will operate most
differently than the industrial sized wineries and the wine refineries. Boutique/small
wineries generally will not have expensive monitoring or operational equipment to make
their wine. Instead they will opt for smaller scale fermentation tanks, blending tanks, and
simpler wine-monitoring methods during fermentation (Goldman, 2018) (Storm, 1997).
An example operational difference between a boutique/small winery and an industrial
sized winery would be the method of testing Brix content. A boutique/small winery may
check each fermentation tank individually for the sugar content, opening and closing the
tank for each test. An industrial sized winery or larger would have electronic equipment
to monitor Brix content to monitor sugar content within their stainless-steel fermentation
tanks: the tanks would not be opened at any point during fermentation to prevent any
possibility of spoilage or loss of ethanol. The Cal Poly pilot winery was classified as a
boutique/small winery because its estimated total tankage volume for production is small
relative to recorded tankage industrial sized wineries or wine refineries (Table 4)
(Goldman, 2018).
Winery Classification Winery Estimated Total Tankage (gallons)
Boutique/Small Cal Poly Pilot Winery 1,300
Industrial Sized Winery Central Coast Wine Services 564,000
Wine Refinery E&J Gallo 4,200,000
Table 4. Select Winery Classifications
25
2.8. California Wine Production and Air Quality
As Californian wine production flourished in the late 20th century, the EPA
assessed the impact of winery emissions on human and environmental health. A review
of winery emissions was conducted and compiled in 1995. It was comprised of two parts:
assessment of the potential for emissions in each step of the wine making process and
evaluating previous research on winery emissions (Midwest Research Institute, 1995).
Ethanol and CO2 were identified as the two compounds most emitted during wine
production (Midwest Research Institute, 1995) (Williams & Boulton, 1983). The
fermentation phase was identified as the step with the most ethanol and CO2 emissions.
The EPA evaluated several emission factor models for ethanol. A 1983 journal article by
R. Boulton and L. Williams proposed a computer model to estimate the ethanol emissions
from fermentation; this model was determined by the EPA to be a reasonable estimate of
fermentative ethanol loss (Williams & Boulton, 1983) (Midwest Research Institute,
1995). The study produced two emission factors that are used by CARB and local
APCDS today: 2.5 lbs. ethanol/1000 gallons white wine produced, and 6.2 lbs.
ethanol/1000 gallons red wine produced (California Air Resources Board, 2005). These
emission factors were used with crush data collected by the United States Department of
Agriculture (USDA) for the 2017 California wine season to calculate the total ethanol
emissions (Table 5) (United States Department of Agriculture, 2018). The USDA’s grape
crush tonnage was multiplied by a factor of 150 gallons of wine production per ton of
grapes crushed to calculate the total gallons of wine produced in 2017 (Gerling, 2011).
26
Wine Production (gallons) Calculated Ethanol Emissions (lb.)
Red 337,239,000 2,091,000
White 264,814,000 662,000
Total Ethanol Emissions (lb.) 2,753,000
2.8.1 Wine Emissions Compared to Other ROG Sources
The CARB and USEPA maintain databases of different sources and their
emissions through an emissions inventory. These inventories include field data for each
source and create an emission rate profile of different constituents such as hydrocarbons,
particulate matter, CO2, and nitrous oxides (California Air Resources Board, 2016). The
CARB further distinguishes hydrocarbon emissions as one of two groups: total organic
gases (TOG) and reactive organic gases (ROG) (California Air Resources Board, 2009).
The CARB defined the terms VOC and ROG as interchangeable. The ROG category
includes all TOGs except carbon monoxide, carbon dioxide, carbonic acid, metallic
carbides or carbonates, ammonium carbonate, and a list of other compounds determined
to be non-reactive by the CARB and the EPA (California Air Resources Board, 2009).
The difference between reactive and non-reactive organic gases is that ROGs contribute
to the formation of photochemical smog because of their photochemical reactivity.
Ethanol is included in the hydrocarbon and ROG category for its photoreactive properties
(Alvim, et al., 2018) (California Air Resources Board, 2009).
Winery emissions represent approximately 0.9% of all VOC emissions in
California during the fermentation season, based on a comparison to previously published
CARB emissions inventory literature on source VOC emissions (Table 6) (California Air
Resources Board, 2016). The ethanol emissions calculated from Table 5 were averaged
Table 5. Calculated Ethanol Emissions from 2017 California Wine Season
27
over 91 days, which is the wine grape harvest season from August 1st to October 31st.
Because wine is not fermented year-round, the harvest time frame was assumed to be
done concurrently with wine fermentation (Midwest Research Institute, 1995) (Robinson,
2006).
Selected Emission Sources VOC Emissions (tons per
day)
% of Total
Emissions
Winery Fermentation (2017) 15 0.9%
Electric Utilities 3 0.2%
Light Duty Passenger Vehicles 158 9.3%
Landfills 16 1.0%
Oil and Gas Production 31 1.8%
Off Road Equipment 119 7.0%
Architectural Solvent
Evaporation 72 4.3%
Total Statewide 1688
2.9 Winery Emissions Control and Regulations
At the federal, state, and local level of government, the United States has taken
efforts to protect the environment. Air quality regulatory agencies have made effort to
evaluate the impact that sources of emissions have on people and their surroundings. This
section covers the following topics:
1. The history of federal, state, and local levels of air quality regulatory bodies.
2. The impact that environmental regulation has had on the wine industry.
3. How the wine industry has directed efforts towards sustainability and improving
environmental health.
Table 6. Comparison of Select Source Emissions of VOCs
28
2.9.1 History of Indoor/Outdoor Air Quality Regulation in the United States
The United States has established several levels of regulatory bodies to propose
and enforce industrial, occupational, and residential IAQ standards. The United States
Environmental Protection Agency (USEPA) was established through the signing of the
Reorganization Plan No. 3 of 1970 (United States Environmental Protection Agency,
2018). Since its creation, the USEPA has been charged with creating and governing
programs and laws to ensure the protection and preservation of environmental health.
However, the USEPA has more responsibility than just air quality regulation: they are
also responsible for other facets of environmental health such as water quality and the use
of manufacturing and processing chemicals. There are 10 regional offices for overseeing
sponsored programs within designated regions of the United States. Each regional office
oversees the enforcement of federal regulations alongside the state and local agencies
(United States Environmental Protection Agency, 2018).
President Nixon also signed the Williams-Steiger Occupational Safety and Health
Act of 1970 that same year (Occupational Safety and Health Administration, 2018). This
act created the Occupational Health and Safety Administration (OSHA) and the National
Institute of Occupational Safety and Health (NIOSH). Since their creation, OSHA and
NIOSH have utilized their research to identify new hazardous compounds and modify
existing exposure limits to keep workers safe. Exposure limits for a given chemical
compound are identified as the permissible exposure limit (PEL), a maximum allowable
concentration for worker exposure to a pollutant (Occupational Safety and Health
Administration, 2018).
29
The EPA and OSHA are both federal programs, setting baseline laws and limits
for the state and local agencies to adhere to. However, California has the authority to
create its own environmental regulations that are more stringent than those set forth by
the federal agencies. Three years after the creation of OSHA, the state of California’s
Department of Industrial Relations passed The California Occupational Health and
Safety Act of 1973 (State of California Department of Industrial Relations, 2016). This
allowed California to pass stricter limits on exposure and worker’s rights than were
administered by the federal OSHA at the time. Cal/OSHA is governed through
California’s Department of Industrial Relations and is responsible for the well-being of
occupational workers throughout the state (State of California Department of Industrial
Relations, 2016).
At the state level, educational programs can be more intimately tailored to inform
residents of potential indoor and outdoor air pollutants. The California Air Resources
Board (CARB) was established in 1967, when Governor Ronald Regan signed the
Mulford-Carrell Act to unite the Bureau of Air Sanitation and the Motor Vehicle
Pollution Control Board (California Air Resources Board, 2018). Today, CARB’s
primary focus is on transportation emissions and “protecting the public from the harmful
effects of air pollution and developing programs and actions to fight climate change”
(California Air Resources Board, 2018). The CARB has also created the Indoor Air
Quality and Personal Exposure Assessment Program, aiming to improve public health
through awareness and education. The California Department of Public Health (Cal DPH)
is another state agency that works with CARB to teach about the relationship between
environmental and personal health. Cal DPH created the Environmental Health
30
Laboratory Branch, the first state-level IAQ health program in the United States. Cal
DPH offers programs and information on potential indoor and outdoor air quality hazards
that are faced by the residents and workers of California (California Department of Public
Health, 2018).
With the establishment of the CARB, the state also created local air districts to aid
in the regulation and monitoring of stationary emission sources (California Air Resources
Board, 2018). There are 35 unique air pollution control districts (APCD) and air quality
management districts (AQMD) throughout California that differ only in name. Both
APCDs and AQMDs are responsible for enforcement of federal, state, and local air
quality regulations within their respective basins.
In short, these regulatory bodies all play a role in air quality regulations and
monitoring: the occupational bodies (e.g. OSHA and Cal/OSHA) are more concerned
with indoor/occupational air quality, while environmental health-based agencies (e.g.
USEPA, CARB, and the APCDs/AQMDs) focus on emission sources and their effect on
air quality.
2.9.2 Winery Emission Regulation
Early research on the environmental impact of wine production was conducted
primarily through the EPA and CARB. As previously stated, the EPA has conducted an
emissions inventory for production of different types of wine and brandy, publishing this
information for regulatory agencies to use for their emissions calculations. Since then, the
CARB has produced an emissions factors model for wine production (California Air
Resources Board, 2005). These resources are used by the APCDs and AQMDs, along
with information provided by the wineries, to create permits to construct and operate
31
winery equipment. These permits pertain to fermentation emissions, boilers, and
generator engines (Santa Barbara County Air Pollution Control District, 2019).
2.9.3 Best Available Control Technologies
The APCDs and AQMDs will call for the implementation of best available
control technologies (BACT) to mitigate emissions of GHGs or VOCs (Santa Barbara Air
Pollution Control District, 2018). Examples of BACT for winery emissions include the
use of wet scrubbers and chiller condensers to mitigate the emissions of VOCs (i.e.
ethanol) during fermentation. Because of ethanol’s high solubility in water, water-based
capture methods are ideal. The two most commonly used technologies are wet scrubbers
and chiller condensers. A wet scrubber is a control device that forces gas through either a
spray or collection of water, stripping the VOCs out of the air and retaining them in the
water for further treatment (Figure 3) (United States Environmental Protection Agency,
2003) (Cooper & Alley, 2011). Chiller condensers decrease the temperature of the VOC-
laden air down to its dewpoint, where the air condenses into water and is collected for
VOC treatment (Figure 4) (United States Environmental Protection Agency, 2001)
(Cooper & Alley, 2011). Both technologies are currently applied to large fermentation
tanks as supplementary piping connected to the top of enclosed fermentation tanks.
32
Figure 3. Basic flow diagram of a wet scrubber
Figure 4. Basic flow diagram of a chiller condenser
33
2.9.4 History of Winery Emission Regulations in California
In December 2005, the San Joaquin Valley APCD approved of the state’s first
winery emissions control regulation for large-scale wineries through Winery Rule 4694.
Winery Rule 4694 was the first of its kind in California: no other APCD nor AQMD had
previously established regulations specifically for the wine industry. This new rule aimed
to curb ethanol emissions from the fermentation and storage of wine in facilities with an
annual ethanol fermentation emission rate of 10 tons or greater. Rule 4694 called for a
minimum 35% reduction in emissions through any combination of three options: onsite
emissions controls, capture of ethanol emissions from non-winery sites, or payments to
district-funded mitigation efforts (San Joaquin Air Pollution Control District, 2005)
(Bustillo, 2005).
Since the creation of Rule 4964, other APCDs and AQMDs in California have
adopted similar regulations for their wineries. Santa Barbara County APCD (SBAPCD) is
another forerunner in creating and overseeing winery emission regulation. On April 26,
2017, Central Coast Wine Services (CCWS) filed for a permit to authorize modifications
in their wine production facilities for expanding production. The SBAPCD approved of
the permit but called for the continued use of BACT on the new fermentation tanks being
used in their facilities. This use of BACT became a heavily debated topic between the
SBAPCD and CCWS. The core issue was whether CCWS’s current use of the ethanol
control technologies constituted as “achieved in practice,” i.e. an established BACT
precedent for other wineries to follow. If it was determined to be “achieved in practice,”
then CCWS would have to implement new control measures on their larger fermentation
tanks. As for future wineries that apply for similar permits from other APCDs/AQMDs,
34
they would also have to adhere to the same BACT requirements as CCWS (Santa Barbara
County Air Pollution Control District, 2018) (Todorov, 2018).
The dispute ended in a settlement June 2018, creating a new requirement for
BACT on indoor fermentation tanks more than 30,000 gallons (Todorov, 2018) (Santa
Barbara County Air Pollution Control District, 2018). This is a potentially landmark case
for wineries across the state of California: the new requirement for control technologies
now applies to mid-sized wineries and larger, increasing operating costs for wine
producers with indoor fermentation tanks larger than 30,000 gallons. These operating
costs may also affect the price of the wine that is produced by these mid-sized wineries,
affecting overall production and profits.
The sentiment towards ethanol capture among wine producers has remained the
same since the establishment of Rule 4694 in 2005: wine makers are willing to contribute
towards cleaner air, but do not believe that the implementation of ethanol control devices
is the best method (Bustillo, 2005). Many wine makers argue that the potential loss of
ethanol and other VOCs that constitute wine aroma will result in a poorer quality product
(Storm, 1997). Additionally, ethanol has been determined by the EPA as a chemical of
low concern, determining that it is a safe ingredient to humans and the environment
(United States Environmental Protection Agency, 2018). Because of its comparatively
low emission levels and ethanol’s safe ingredient designation, mitigation requirements
have been fought against by wine producers since the publication of the 1995 emissions
study and continues to be a topic of debate (Todorov, 2018) (Storm, 1997).
35
3. Experimental Methods
The experimental methods for determining VOC concentrations within the winery
workspace and ethanol emission rates are explained in this section. A preliminary carbon
dioxide (CO2) tracer-gas experiment was deployed to determine the indoor air exchange
rate of the winery workroom, which was used to estimate ethanol emission rates from the
indoor concentrations. Air samples were collected from within the workroom during
different activity periods using active sampling and sorbent tubes. These samples were
analyzed using thermal desorption gas chromatography-mass spectrometry (GC-MS)
methods adapted from similar indoor VOC monitoring studies to determine the indoor
concentration of VOC contaminants inside of the winery workroom.
3.1 Tracer Gas Air Exchange Test Theory
An air exchange rate (AER) test can be conducted through several different
methods: blower door test, duct blaster test, flow hood test, and the tracer gas decay test
(Hancock, Norton, & Hendron). This study utilized the tracer gas decay test for its ease of
implementation and affordability.
The tracer gas test relies on two assumptions:
1. The concentration of the tracer gas is well mixed inside of the system.
2. There are no sources, reactions, or losses in the system.
The mass balance equation referenced in Section 2.5.2 was modified to fit this
tracer gas decay study approximation. Applying the two assumptions to the mass balance
equation, the equation can be simplified:
36
∆Co ∗ V
∆t= Outdoor Source Generation − Ventilated Outside
C0 = initial concentrations of constituent, ppm
V = Volume of building space
t = time
The “Outdoor Source Generation” and “Ventilated Outside” terms were
simplified to be the concentration of the tracer gas entering or leaving the building
multiplied by the flowrate of air entering and exiting the indoor space:
∆Co ∗ V
∆t= Center ∗ Qenter − Cexit ∗ Qexit
Qenter = entering air volumetric flow rate, Volume
Time
Qexit = exiting air volumetric flow rate, Volume
Time
Center = entering air concentration of constituent
Cexit = exiting air concentration of constituent
For a well-mixed system with no sources or losses in the building space, the
previous equation is integrated to become:
Ct = C0 ∗ e−λt + Center ∗ (1 − e−λt)
Ct = concentration at time t
C0 = initial concentration at time t = 0
Center = concentration of contaminant in entering air
t = time
λ = time-1
(3.1)
(3.2)
(3.3)
37
Equation 3.3 is the non-ideal tracer gas decay equation. To simplify the
calculations, an ideal tracer gas could be used. An ideal gas is one that does not occur
naturally in the environment of the test, i.e. Center will be zero.
The non-ideal tracer gas equation was used with tracer gas test data with the
initial parameters C0 and Center measured. Then, an estimated λ was used, comparing the
estimated Ct values with field-measured concentrations Ct. The estimated λ was
determined so that the modeled concentrations from the non-ideal tracer gas equation
were approximately equal to the measured concentrations. An average AER was
calculated from 4 tests.
3.1.2 Tracer Gas Decay Air Exchange Test Method Design
For this study, CO2 was the chosen tracer gas for its accessibility and affordability
(Cui, Cohen, Stabat, & Marchio, 2015) (You, et al., 2012). The CO2 was injected into the
winery workroom instantaneously via gas bags and allowed to mix inside of the winery
workroom for 5 minutes, achieving maximum concentrations of 2,500 ppm; this
concentration allowed a long enough decay period to determine the AER. Gas bags were
filled with 30 ft3 of 99% purity CO2 and were placed at 5-foot elevations inside of the
room. 12 gas bags were used, placing four equally-distanced rows of three bags from the
north to the south end of the room. Preliminary background CO2 level concentration tests
yielded average concentrations ranging from 468 ppm to 582 ppm. All windows and
doors into the space were kept closed during the mixing period. After 5 minutes of
mixing, the doors and windows in the space were opened to simulate the conditions that
the workroom is usually operated in when workers are present. Entry into the building
was restricted during the test so that inadvertent mixing inside of the workroom was
38
mitigated and no human produced CO2 during the test. After a 15-minute measurement
period, the space was allowed to air out any remaining CO2 inside of the room.
CO2 data was collected using two Fluke 975 Indoor Air Quality Meters, set at 3
feet and 8 feet above the floor at the south and center of the room, respectively (Figure
5). Placing meters near the roll-up door at the northern end of the room yielded CO2
concentration drops that were too rapid for analysis using the tracer gas decay equation,
indicating that they were primarily measuring outdoor air blowing past the sensor. While
this is an important consideration for a model that includes multiple spaces with differing
AERs, the model used in this study focused on a single space assumption. The tracer gas
decay testing was conducted two weeks prior to the anticipated crush and fermentation
period during September 2018 to simulate anticipated weather conditions: wind speed
and wind direction have been shown to play a role in a building’s AER (Hancock,
Norton, & Hendron). Thus, testing the AER during crush and fermentation anticipated
weather conditions allowed for a more relevant estimate of the winery workroom’s AER.
AER measurements could not be made during the VOC sampling period because CO2
generation by workers and the fermentation process would interfere with the tracer gas
decay.
39
3.1.3 Determination of AER
Because CO2 was used as the tracer gas in this air exchange test, non-zero outdoor
CO2 concentrations meant that the ideal gas assumption could not be made. Outdoor
background CO2 measurements were taken before each test to determine the Center term.
The declining tracer gas concentration was modeled using the AER which created the
best line of fit for the data (Figure 6). The average AER from the four testing periods was
8.9 ± 1.9 hr-1. Winery ventilation is governed by the ASHRAE published standards 62,
calling for a minimum ventilation rate of 20 cubic feet per minute (cfm) per person
(Storm, Winery Utilities). This winery workroom has a volume of 9000 cubic feet; when
multiplied by the average AER of 8.9 hr-1, the average ventilation rate was 1,335 cfm.
This ventilation rate is acceptable for the operations that take place within the workroom,
which hosts up to 15 students and professors at a time performing their vinification
Figure 5. Basic layout of the winery workroom showing locations of Fluke 975 meters
measuring CO2 Concentrations
40
duties. Typical ventilation rates for a winery mechanical workroom are 3 to 12 hr-1
(Winery Utilities).
3.2 Sampling Methods
Sampling methods followed the protocol outlined in EPA Method TO-17. Twenty
sorbent tubes (Stainless Steel Thermal Desorption Tubes Anasorb GCB1/Carbosieve S-
II) were used in total for the sampling procedures. Two method blanks, two trip blanks,
and two field blanks were implemented for quality assurance monitoring during sample
handling. The remaining fourteen sorbent tubes were used for collecting air samples at
the workroom.
3.2.1 Sorbent Tube Preparation and Storage
Sorbent tube conditioning is an essential part of sorbent tube analysis.
Conditioning was performed by heating the sorbent within the tube to temperatures up to
350 °C while an inert carrier gas flowed through the tube, purging any unwanted
compounds that could interfere with subsequent analysis. For this study, sorbent tubes
0
100
200
300
400
500
600
700
800
900
1000
10 15 20 25 30 35
pp
m C
O2
Time (min)
Collected Data
Expected Values from Model
Figure 6. Tracer gas decay modeling for data collected from 9-7-2018 plotted using an AER
of 10.2 hr-1
41
were conditioned and purged using the Markes Unity 2 thermal desorption unit. Tubes
were initially conditioned at 350 °C for two hours at a helium gas flow rate of 100 mL
per minute: this is in accordance with the TO-17 recommended guidelines for
conditioning sorbent tubes with the Anasorb GCB1 sorbent (TO-17). In between
samplings, tubes were conditioned for 30 minutes; this was performed so that background
compounds sorbed onto the tubes were kept as low as possible (Jing Chen et. al, Study on
Thermal Desorption). Once conditioned, sorbent tubes were capped, wrapped in
aluminum foil, and placed in an opaque glass container. The container was stored in a
refrigerator at 4 °C until the sorbent tubes were needed for sampling.
3.2.2 Pump Calibration
Low volume sampling pumps were used for the sample collection of winery
workroom air: one SKC Pocket Pump Touch, two SKC Pocket Pumps, and one Byron
model 10 sampling pump. A flowrate of 200 mL per minute was selected: this is the
recommended maximum flowrate for sorbent tubes per TO-17 to prevent channeling
within the sorbent medium. Flow rate calibrations were performed with the Gilian
Gilibrator 2 calibration system. Per TO-17 methods recommendations, pre-sampling
calibrations of the pumps incorporated the sorbent tubes in the calibrations set-up,
allowing for accurate adjustments to the pump flow rate as required. The pumps were
transported to and from the workroom via carrier bag.
3.2.3 Site Sampling Set Up
For the first sampling session, sampling pumps were placed at the two ends and
center of the workroom. The workroom itself is used for educational purposes and hosts a
variety of equipment and activities throughout the area. Pump 1 was placed adjacent to
42
the roll-up door, which was always open during workroom operation and sampling. Pump
2 was placed in between two blending tanks that were not in use during any of the
sampling periods, and across the room from where the fermentation tanks and basins are
kept in the workroom. Near Pump 3, the open windows face towards an active road and
parking lot. Cleaning equipment and supplies are also kept in shelving adjacent to the
windows. Pumps were kept at an elevation of four feet, equal to the elevation of the
fermentation tanks’ openings and within the exposure elevation for building occupants.
After the first sampling session, a fourth sampling pump was obtained so that
outdoor concentrations could be monitored as well. Sessions 2, 3, and 4 utilized the four-
pump set-up to measure for indoor and outdoor air concentrations of the select VOCs
(Figure 7). The indoor pump locations were not altered between each session.
For all four sampling sessions, sorbent tubes were distributed to each pump
randomly until all 14 sampling tubes and 2 field blank tubes were distributed equally
among the four sampling pumps. This allowed for multiple samples to be collected at
each pump during the sampling session. Including site preparation, sampling, and site
clean-up, the duration of each sampling session averaged 3 hours.
43
The workroom is located on the corner of a busy road leading into the Cal Poly
campus, an access road for agricultural equipment or commuters, and adjacent to a staff
parking lot. Additionally, it is located in between four agricultural practice fields, which
are used and maintained throughout the year (Figure 8).
Figure 7. Pump locations in winery workroom for Session 2 on November 16, 2018;
Session 3 on November 19, 2018; Session 4 on November 30, 2018. Pump 4 was not
operational during Session 1.
44
3.3 Gas Chromatography-Mass Spectrometry Methods
Liquid standards of benzene, toluene, ethylbenzene, xylene, and ethanol were
obtained from Millipore Sigma (Table 7). The method of injecting liquid calibration
standards onto sorbent tubes followed the methods outlined in TO-17 Section 9.3 Liquid
Standards (TO-17). Liquid standards were injected onto sorbent tubes via 5 µL micro-
syringe injections. The sorbent tubes were then placed into the thermal desorber and
purged using the thermal desorption GC-MS settings optimal for sample analysis (Tables
8, 9, 10) (Air Monitoring, Monitoring of VOCs, Newspapers, Development of Improved
Methods). Thermal desorption GC-MS analysis of field samples was conducted using the
same operating parameters used for liquid injection calibrations.
Figure 8. Site map of winery workroom and surrounding area (Google, n.d.)
45
Table 7. VOC Compound Standards
Compound Mass of Compound in 1 mL (µg)
Benzene 200
Toluene 200
Ethylbenzene 5000
M-Xylene 5000
O-Xylene 5000
P-Xylene 5000
Ethanol 2000
Table 8. Sorbent Tube Desorption Parameters
Purge time (trap in-line) 1 min
Desorption time 10 min
Desorption temperature 300 °C
Temperature of cold trap -10 °C
Desorption flow 20 mL/min
Split flow 44 mL/min
Carrier gas pressure 15 psi
46
Table 9. Focusing Trap Desorption Parameters
Desorption time 3 min
Temperature of cold trap 300 °C
Split flow 44 mL/min
Temperature of transfer line 150 °C
Table 10. GC-MS Parameters
Carrier gas flow 1.7 mL/min
Oven start temperature 40 °C
Hold start temperature 9 min
Ramp temperature rate 20 °C/min
Ramp temperature finish 200 °C
Hold ramp temperature 2 min
47
4. Results and Discussion
Methods discussed in Section 3 were applied to calculate the air exchange rate
(AER) of the winery workroom during VOC sampling. The indoor concentrations of
ethanol and benzene during VOC sampling were estimated using GC-MS output readings
and calibration curves. The AER and indoor concentrations were combined to determine
emission rates from the workroom during each activity. Finally, typical activity durations
for a hypothetical 14-day wine-making process were assumed to calculate an ethanol
generation rate per 1000 gallons of wine produced.
4.1 Air Exchange Rate Determination
After the data from each tracer gas decay test were recorded and plotted, an AER
for each test was estimated to best fit the decay of the CO2 (Table 11). The average AER
was 8.9 ± 1.9 hr-1. Weather conditions for the tracer gas decay test days were analyzed to
determine the relationship between windspeed,
wind direction, and AER (Table 12). Weather
reports indicated that wind blew from the west or
northwest of the workroom during the tracer gas
decay test days (Weather Underground, 2019).
Additionally, the two days with the highest
recorded wind speeds during testing also
had the highest AER values. It was
concluded that westerly and north-
westerly wind direction and high wind
speed are the two major contributors to the workroom’s AER. The wind direction’s
Table 11. Calculated AERs from
Tracer Gas Decay Tests
Date λ (hr-1) Precision (±)
9/7/2018 10.2 1.2
9/9/2018 7.5 1.2
9/12/2018 10.8 1.2
9/13/2018 6.9 1.2
Average 8.9 1.9
Table 12. Calculated AERs and Wind Data
Date Wind mph AER Direction
9/7/2018 18.4 10.2 NW
9/9/2018 9 7.5 W
9/12/2018 18.4 10.8 NW
9/13/2018 12.7 6.9 NW
48
contribution to AER seemed feasible, as the large roll-up door is located at the northern
side of the winery workroom. Using these assumptions, a simple linear regression model
was created to estimate the AER of the winery workroom on VOC sampling days (Figure
9). To determine the applicability of the model, weather conditions for VOC sampling
and the tracer gas decay test sessions were compared. Weather reports confirm that the
wind during VOC sampling days generally blew from the NW as well (Weather
Underground, 2019). However, the wind speed on VOC sampling days were lower than
those on the AER testing days: therefore, AERs for the VOC sampling days were
extrapolated from the linear regression model to estimate an AER for the given VOC
sampling day (Table 13).
y = 0.3728x + 3.3972R² = 0.7889
0
2
4
6
8
10
12
0 2 4 6 8 10 12 14 16 18 20
AER
(h
r-1)
Wind Speed (mph)
Figure 9. Air exchange rate (AER) vs. wind speed model for winery workroom
49
Date Wind mph AER Direction
10/16/2018 7 6.0 NW
11/16/2018 7 6.0 NW
11/19/2018 3 5.3 -
11/30/2018 9 6.8 N
4.2 VOC Calibration Curves for GC-MS
To determine the indoor concentration of the selected VOCs in the winery
workroom, a linear relationship was established between the GC-MS data output and the
mass sorbed onto the sorbent tubes using a calibration curve: a linear regression model
that established a mathematical relationship between the mass of the select VOC on the
tube and abundance, the GC-MS’s output measurement. Calibration curves were made
for benzene (Figure 10) and ethanol (Figures 11 and 12). After initial calibration curves
were created, GC-MS analysis determined that a single calibration curve for ethanol
would not be feasible: recorded ethanol GC abundance values differed by as much as
three orders of magnitude. To account for the wide range of ethanol abundance, two
calibration curves were created, one for the lower concentrations and a second for the
upper magnitudes of the range. Only one benzene calibration curve was created because
field samples were all within the bounds of the curve. Calibration curve creation
determined that the precision of the ethanol and benzene concentrations were ± 2 and 1
µg/m3, respectively.
Table 13. VOC Sampling Date and Estimated AER
50
y = 1.0568x + 0.0152R² = 0.9972
0.0
0.2
0.4
0.6
0.8
1.0
1.2
0.0 0.2 0.4 0.6 0.8 1.0 1.2
GC
Ab
un
da
nce
(1
06)
Mass Injected (µg)
y = 1.7947x + 0.0097R² = 0.9996
0.00
0.50
1.00
1.50
2.00
2.50
0.00 0.20 0.40 0.60 0.80 1.00 1.20 1.40
GC
Ab
un
da
nce
(1
06)
Mass Injected (µg)
Figure 11. Upper range ethanol calibration curve
Figure 10. Benzene calibration curve
51
4.2.1 Absence of Calibration Curves for Ethylbenzene, Toluene, and Xylene
The original sampling plan included the quantification of ethylbenzene, toluene,
and xylene. However, due to the GC-MS set-up being utilized, calibration curves were
not able to be created. During trial calibration runs, ethylbenzene and xylene were unable
to be identified by the GC-MS at any mass injected for analysis. Toluene was similarly
difficult to quantify using the available GC-MS set-up: it was indistinguishable from the
background noise during GC-MS analysis, even at the highest mass injections available.
Due to these complications, only ethanol and benzene were able to be reliably quantified
and analyzed. However, since fossil fuel combustion is expected to be the primary source
for benzene, toluene, ethylbenzene, and xylene at the sampling locations, benzene is a
reasonable indicator of exposure even without the other compounds.
y = 1.4879x + 7.742R² = 0.9989
0
100
200
300
400
500
600
700
0 50 100 150 200 250 300 350 400 450
GC
Ab
un
da
nce
(1
06)
Mass injected (µg)
Figure 12. Lower range ethanol calibration curve
52
4.3 Indoor Concentrations of Ethanol and Benzene Inside of Winery Workroom
Four different activites occured inside of
the winery workroom during each the VOC
sampling dates: fermentation, Brix content testing,
post-fermentation pressing, and finished wine
storage (Table 14). Samples collected from the
winery workroom were analyzed with the GC-MS
to produce a chromatograph (Figure 13). The chromatographs were integrated using the
GC-MS software to determine the GC abundance values for ethanol and benzene. The
abundance values were used in the calibration curve equations to determine the mass that
was collected on each sorbent tube. The sampling volume for each tube was 4 L of air:
dividing the mass collected by the sampling volume yielded the indoor air concentration
for ethanol and benzene for each sample collected (Figures 14 and 15).
Indoor Concentration (grams
m3) =
Mass Collected on tube (g)
Sampling volume (L)∗
1000 L
m3 (4.1)
As stated in section 2.2.3, multiple VOC samples were collected at each pump
throughout each sampling session. Samples collected at their respective pump locations
were averaged to estimate the ethanol and benzene concentrations. Then, these averages
were used to calculate an overall average concentration for the entire winery workroom.
Sampling pump 4 was set up outside of the workroom and not representative of the
indoor concentrations, thus was not included in the indoor concentration estimate. The
purpose of sampling pump 4 was to determine if similar concentrations of ethanol and
benzene were observed just outside of the winery workroom, testing the legitimacy of the
boundary line assumed for the mass balance model. Concentrations were averaged for
Date Activity Type
10/16/2018Fermentation / Brix
Content Test
11/16/2018 Fermentation
11/19/2018Pressing Post-
Fermentation
11/30/2018 Storage
Table 14. Sampling Date and
Activity Type
53
each of the indoor sampling locations because the AER model used assumes that the
room is well mixed, i.e. the concentration of benzene or ethanol is equal throughout the
room. The large peak identified between ethanol and benzene was assumed to be ethyl
acetate, based on readings from the GC-MS database. However, the GC-MS database
provided too many possibilities at the 3-minute peak to confidently hypothesize the
corresponding chemical compound.
Figure 13. GC-MS chromatograph from sample AS07 collected on November 19,
2018
54
0.00
0.05
0.10
0.15
0.20
1 2 3 4
Ben
zen
e C
on
cen
trat
ion
(m
g/m
3)
Pump Location
11/30/2018
11/16/2018
10/16/2018
11/19/2018
0
5
10
15
20
25
1 2 3 4
Eth
ano
l co
nce
ntr
atio
n (
mg
/m3)
Pump Location
Storage
Fermentation
Fermentation/BrixContent Test
Pressing Post-Fermentation
Figure 14. Benzene concentration by pump location and date
Figure 15. Ethanol concentration by pump location and activity type
55
Average benzene concentrations were calculated for each sampling day (Table
15). As previously stated, benzene is not a direct product of wine fermentation. Rather, it
is a prevalent VOC by-product of engine combustion. All observed benzene
concentrations during VOC sampling were greater than the benzene concentrations
determined from the Sanjuan-Herrarez et. al study. This is likely due to the roads and
agricultural fields that are so close to the pilot winery.
Date Average Benzene Concentration (mg/m3)
10/16/2018 0.09
11/16/2018 0.06
11/19/2018 0.12
11/30/2018 0.05
Average ethanol concentrations in the winery workroom were determined to be
greatest during the pressing post-fermentation activity and the fermentation with Brix
content testing activity, while the fermentation without Brix content testing and storage
activities had the lowest ethanol concentrations (Table 16).
Activity Average Ethanol
Concentration (mg/m3)
Fermentation 0.36
Storage 0.09
Fermentation/Brix Check 8.4
Pressing Post-
Fermentation 12
The most significant field condition difference between each activity is the
opening of the fermentation tanks. For Brix content testing, each fermentation vessel was
opened for several minutes while Brix content was measured. In the post-fermentation
pressing, each fermentation vessel is opened and emptied into the pressing equipment for
Table 15. Average Workroom Benzene Concentrations by Sampling Day
Table 16. Average Workroom Ethanol Concentrations by Activity
56
full extraction of juices. During pressing, the finished wine is inadvertently sprayed into
the workroom air, increasing the amount of airborne ethanol and other VOCs. As for the
fermentation and storage activities, there was no opening of fermentation or storage tanks
during VOC sampling. However, ethanol and CO2 were released through the airlock
system on the fermentation vessels. Airlocks and similarly functioning apparatuses are
used to release the CO2 produced during fermentation while avoiding the introduction of
outside air into the vessel, keeping oxygen out of the fermentation environment to avoid
spoiling (Figure 16).
4.3.1 Analysis of Sampling Quality Assurance and Quality Control
Method blanks, trip blanks, and field blanks were incorporated into the quality
assurance and quality control measures to determine the efficacy of sorbent tube
decontamination during desorption, as well as identify any possible issues during sample
transportation and field sampling. During method and trip blank analysis, detectible
levels of ethanol and benzene were detected on the sorbent tubes between sampling and
conditioning sessions, averaging an equivalent ethanol and benzene sampling
concentration of 0.04 and 0.02 mg/m3, respectively (Table 17). This is likely an indicator
of sorbent tube conditioning between sampling sessions not being conducted for a
Figure 16. Typical Fermentation Locks (Pressure Cooker Outlet, 2019)
57
sufficient duration. These persistent masses of ethanol and benzene were subtracted from
their respective initial concentrations calculated in Figures 14 and 15 to more accurately
estimate concentrations sampled in the workroom.
4.3.2 Ethanol Concentration Variation Between Samples, Pumps, and Activity
Sample concentrations of ethanol varied between pump locations, as well as
between samples at a single pump (Table 18 and Table 19). It is speculated that the
observed variability is due to the imperfect circulation throughout the winery workroom,
variation in activity level during sampling. For example, during fermentation and Brix
content testing on October 16, 2018, calculated ethanol concentrations at Pump 2 ranged
from 0.07 to 12.74 mg/m3. Fermentation tanks near Pump 2 were intermittently opened
and closed throughout sampling, possibly resulting in concentrations varying by as much
as 3 orders of magnitude.
Sample # Ethanol concentration (mg/m3) Average Concentration
(mg/m3)
Standard Deviation
(mg/m3)
AS04 52
11 23
AS10 0.49
AS12 1.7
AS13 2.5
AS14 0.04
Table 17. Ethanol and Benzene Concentration Equivalent Measurements on Method Blanks
(mg/m3)
10/16/2018 11/16/2018 11/19/2018 11/30/2018
Ethanol 0.01 0.05 0.06 0.02
Benzene 0.01 0.02 0.02 0.02
Table 18. Fermentation w/ Brix Content Test Activity Pump 3 Ethanol Concentrations by
Sample Number
58
This level of variability between samples and sampling pumps was also present
in the post-fermentation pressing activity. However, because each activity was only
sampled once, it is unknown whether the variation is consistent between different
occurrences of the activity.
4.3.3 Indoor Air Concentration Compliance with OSHA Regulations
There were no OSHA or Cal/OSHA violations for either benzene or ethanol
concentrations observed within the winery workroom during the sampling periods (Table
20).
Substance OSHA 8-hour
TWA (ppm)
Cal/OSHA 8-
hour TWA
(ppm)
10/16/18
(ppm)
11/16/18
(ppm)
11/19/18
(ppm)
11/30/18
(ppm)
Benzene 10 1 0.03 0.02 0.04 0.02
Ethanol 1000 1000 4.48 0.19 6.48 0.05
Compliance with the benzene limits was expected: the winery workroom was
located approximately 60 ft. north and 130 ft. west of the two adjacent roads. Being
upwind from the roads also reduced the amount of benzene (i.e. engine emissions)
introduced into the workroom. As for ethanol, the batches of wine that were stored and
Table 19. Fermentation w/ Brix Content Test Activity Ethanol Concentrations by Pump
Number
Pump # Average Ethanol
Concentration (mg/m3)
Average Concentration
(mg/m3)
Standard Deviation
(mg/m3)
1 9.6
8.4 3.7 2 4.2
3 11
Table 20. Comparison of OSHA and CAL/OSHA Exposure Limits to Calculated
Concentrations
59
worked with inside of the workroom were relatively small, not exceeding one ton of
grape crush. If grape crush were to be increased, indoor ethanol concentrations would be
expected to increase as well. In addition, opening the large roll-up door creates a large air
exchange rate which reduces the concentration within the workroom. Although the
OSHA and Cal/OSHA requirements were met, field observations and personal accounts
of the students who have worked in the workroom determined that the aroma in the
winery workroom is quite pungent, especially in previous years when the crush tonnage
was larger. Graduate students assisting this study with their time and data confirmed that
in years with larger crush tonnage, the build-up of fermentation emissions when the
workroom was closed overnight was overpowering to the point of needing to air the
space out before coming inside. For a hypothetical situation of ethanol levels exceeding
the OSHA 8-hour time weighted average, the air exchange rate of the winery workroom
would be 0.00011 hr-1 during the day with the highest VOC concentrations calculated.
4.4 Calculated Emissions for Each Workroom Activity
Emission rates were calculated using the estimated AER model from Section 4.1
and the indoor concentration values that were calculated in Section 4.3.
Emission Rate = Cindoor ∗ Vroom ∗ λ (4.2)
Cindoor = average indoor concentration (g/m3)
Vroom = volume of room (m3)
λ = AER of room (hour-1)
60
To assess the emission levels, regulatory agencies in California have relied on
emission units of pounds ethanol per 1000 gallons of wine produced. The following
assumptions were used to determine the source generation per units of wine production:
1. Emissions were assumed constant over the 3-hour VOC sampling to calculate a
per-hour ethanol emission rate.
2. Three-fourths ton grapes were crushed to produce the batches of wine being
fermented and stored in the winery workroom during VOC sampling.
3. 1 ton of grapes produces 150 gallons of wine (Gerling, 2011).
4. Total hours of activity durations were assumed to determine emission rates over
the duration of a 14-day wine-making process (Table 21). These activities do not
encompass all activities in vinification, but rather the ones sampled for in this
study.
Activity
Assumed
Duration
(hours)
Emission
Rate
(lb/hour)
Total
Estimated
Emissions
(lb)
Emission Rate (lb/1000
gallons)
Fermentation 168 4.80E-04 0.08 0.72
Storage 96 1.18E-04 0.01 0.10
Fermentation/Brix
Check 14 1.13E-02 0.16 1.40
Pressing Post-
Fermentation 6 1.63E-02 0.10 0.87
Total ethanol emissions
(lb/1000 gallons) 3.1
The calculated value of 3.09 lbs. ethanol emissions per 1000 gallons wine
produced is less than the emission factor of 6.20 lbs. ethanol per 1000 gallons wine
produced that is currently used by CARB for their red wine emission calculations. This
emission rate is also lower than the red wine ethanol emission rates determined in studies
Table 21. Ethanol Generation Values by Activity
61
reviewed by the USEPA Emission Factor Documentation for AP-42 Section 9.12.2 Wine
and Brandy Final Report, which range from 3.6 to 5.9 lbs. ethanol per 1000 gallons of
wine produced.
4.5 Issues Encountered During Study
Desorption duration proved to be insufficient for lower ethanol-emission
activities. While this is a minor issue that was encountered, future research using thermal
desorption should perform a preliminary study on sufficient desorption times for
contaminant removal.
Each activity type in this study was sampled for only once for one day, rather than
multiple times throughout the wine season. As a result, possible variations between
multiple instances of one activity were not captured in this study. These variations could
affect the indoor concentrations of ethanol within the winery workroom, and ultimately
result in a different ethanol emission rate. Thus, the calculated 3.1 lbs. ethanol per 1000
gallons wine produced is specifically for the four activities that were sampled for in this
study.
62
5. Conclusion
This thesis project focused on two objectives:
1. Evaluate the indoor concentrations of ethanol and benzene in the Cal Poly pilot
winery using active sampling.
2. Calculate ethanol emission rates within the winery workroom during the selected
wine making activities.
Active sampling allowed for the controlled intake of workroom air, which was
used for the calculation of the indoor air concentrations of benzene and ethanol.
Additionally, the use of thermal desorption (TD) and GC-MS technology to asses VOCs
collected on the sorbent tube was simple to perform when equipment was operational.
Replicated TD GC-MS operating parameters from previous studies allowed for quality
control during GC-MS result analysis.
Ethanol concentrations within the winery varied between the four activities:
average indoor concentrations of ethanol ranged from 0.09 to 12 mg/m3, and average
indoor concentrations of benzene ranged from 0.05 to 0.12 mg/m3. Assuming the
duration of each activity over a 14-day wine-making process, ethanol emissions were
calculated to be 3.1 lbs. of ethanol per 1000 gallons of wine produced. This ethanol
emission rate is specifically for the activities sampled for during this study for this winery
and is not directly applicable to any other winery. However, studies on other wineries and
their process emissions should be evaluated
63
5.1 Future Areas of Research
This study focused on two primary VOCs: ethanol and benzene. Outdoor
emissions of both VOCs contribute to the formation of photochemical smog and degrade
into more photoreactive compounds (Slominska, Konieczka, & Maniesnik, 2014) (Alvim,
et al., 2018). Ethanol is produced by the winery and benzene is introduced from outdoor
sources. Future winery emissions studies should focus on identifying and quantifying
indoor and outdoor concentrations of emitted VOCs and their photodegradation products.
Other VOCs contained in the wine aroma should also be identified and evaluated for their
potential to contribute to photochemical smog formation.
The indoor air model used to calculate the winery workroom concentrations of
ethanol and benzene was a simplification that assumed a single AER for the entire winery
workspace. The reality is that there are likely different AERs throughout the room: the
space near the large, open, roll-up door may have had a different AER than a corner of
the room far away from open windows and doors. Air currents within the room due to the
open windows and doors may also influence the AER around the room. A future study
that measures indoor concentrations of VOCs within an indoor space should evaluate the
AER using a multiple-space model, rather than a single-space model. This would allow
for a more accurate representation of the air flowing in and out of the room and
estimation of the movement of VOCs in and out of the indoor space. However, it would
also require a significant increase in the number of sampling locations.
The use of an averaged indoor air concentration to estimate the average ethanol
emission rate of all activity in the winery workroom during sampling may not be the most
accurate method of evaluating emissions. Previous studies identified by the EPA sampled
64
for ethanol emissions at the direct outlet of the CO2 stream from an individual
fermentation tank. However, this method does not capture fugitive emissions from other
sources. Future ethanol emission studies should compare the efficacy of individual-
stream analysis versus the evaluation methods used in this study for both large and small-
scale wineries.
65
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74
A. CARB 2016 ROG Emissions Inventory
YEAR AREA SRC_TYPE CATEGORY SUBCATEGORY ROG (tons per day)
2012 CALIFORNIA STATIONARY FUEL COMBUSTION ELECTRIC UTILITIES 2.8
2012 CALIFORNIA STATIONARY FUEL COMBUSTION COGENERATION 2.38
2012 CALIFORNIA STATIONARY FUEL COMBUSTION
OIL AND GAS
PRODUCTION
(COMBUSTION)
1.98
2012 CALIFORNIA STATIONARY FUEL COMBUSTION PETROLEUM REFINING
(COMBUSTION) 2.9
2012 CALIFORNIA STATIONARY FUEL COMBUSTION MANUFACTURING AND
INDUSTRIAL 6.07
2012 CALIFORNIA STATIONARY FUEL COMBUSTION
FOOD AND
AGRICULTURAL
PROCESSING
3.06
2012 CALIFORNIA STATIONARY FUEL COMBUSTION SERVICE AND COMMERCIAL
8.17
2012 CALIFORNIA STATIONARY FUEL COMBUSTION OTHER (FUEL
COMBUSTION) 0.79
2012 CALIFORNIA STATIONARY WASTE DISPOSAL SEWAGE TREATMENT 0.9
2012 CALIFORNIA STATIONARY WASTE DISPOSAL LANDFILLS 16.17
2012 CALIFORNIA STATIONARY WASTE DISPOSAL INCINERATORS 1.43
2012 CALIFORNIA STATIONARY WASTE DISPOSAL SOIL REMEDIATION 0.16
2012 CALIFORNIA STATIONARY WASTE DISPOSAL OTHER (WASTE
DISPOSAL) 34.03
2012 CALIFORNIA STATIONARY CLEANING AND SURFACE
COATINGS LAUNDERING 1.23
2012 CALIFORNIA STATIONARY CLEANING AND SURFACE
COATINGS DEGREASING 32.15
2012 CALIFORNIA STATIONARY CLEANING AND SURFACE
COATINGS
COATINGS AND RELATED PROCESS
SOLVENTS
56.14
2012 CALIFORNIA STATIONARY CLEANING AND SURFACE
COATINGS PRINTING 17.36
2012 CALIFORNIA STATIONARY CLEANING AND SURFACE
COATINGS
ADHESIVES AND
SEALANTS 19.68
2012 CALIFORNIA STATIONARY CLEANING AND SURFACE
COATINGS
OTHER (CLEANING AND
SURFACE COATINGS) 8.95
2012 CALIFORNIA STATIONARY PETROLEUM PRODUCTION AND
MARKETING
OIL AND GAS
PRODUCTION 30.64
2012 CALIFORNIA STATIONARY PETROLEUM PRODUCTION AND
MARKETING PETROLEUM REFINING 11.9
2012 CALIFORNIA STATIONARY PETROLEUM PRODUCTION AND
MARKETING
PETROLEUM
MARKETING 64.9
2012 CALIFORNIA STATIONARY PETROLEUM PRODUCTION AND
MARKETING
OTHER (PETROLEUM PRODUCTION AND
MARKETING)
0.28
2012 CALIFORNIA STATIONARY INDUSTRIAL PROCESSES CHEMICAL 16.8
2012 CALIFORNIA STATIONARY INDUSTRIAL PROCESSES FOOD AND
AGRICULTURE 17.42
2012 CALIFORNIA STATIONARY INDUSTRIAL PROCESSES MINERAL PROCESSES 3.44
2012 CALIFORNIA STATIONARY INDUSTRIAL PROCESSES METAL PROCESSES 0.42
2012 CALIFORNIA STATIONARY INDUSTRIAL PROCESSES WOOD AND PAPER 2.47
2012 CALIFORNIA STATIONARY INDUSTRIAL PROCESSES GLASS AND RELATED
PRODUCTS 0.02
2012 CALIFORNIA STATIONARY INDUSTRIAL PROCESSES ELECTRONICS 0.28
75
2012 CALIFORNIA STATIONARY INDUSTRIAL PROCESSES OTHER (INDUSTRIAL
PROCESSES) 11.18
2012 CALIFORNIA AREAWIDE SOLVENT EVAPORATION CONSUMER PRODUCTS 208.71
2012 CALIFORNIA AREAWIDE SOLVENT EVAPORATION
ARCHITECTURAL
COATINGS AND
RELATED PROCESS SOLVENTS
71.74
2012 CALIFORNIA AREAWIDE SOLVENT EVAPORATION PESTICIDES/FERTILIZERS 44.65
2012 CALIFORNIA AREAWIDE SOLVENT EVAPORATION ASPHALT PAVING /
ROOFING 24.48
2012 CALIFORNIA AREAWIDE MISCELLANEOUS PROCESSES RESIDENTIAL FUEL
COMBUSTION 54.38
2012 CALIFORNIA AREAWIDE MISCELLANEOUS PROCESSES FARMING OPERATIONS 127.84
2012 CALIFORNIA AREAWIDE MISCELLANEOUS PROCESSES CONSTRUCTION AND
DEMOLITION 0
2012 CALIFORNIA AREAWIDE MISCELLANEOUS PROCESSES PAVED ROAD DUST 0
2012 CALIFORNIA AREAWIDE MISCELLANEOUS PROCESSES UNPAVED ROAD DUST 0
2012 CALIFORNIA AREAWIDE MISCELLANEOUS PROCESSES FUGITIVE WINDBLOWN
DUST 0
2012 CALIFORNIA AREAWIDE MISCELLANEOUS PROCESSES FIRES 0.67
2012 CALIFORNIA AREAWIDE MISCELLANEOUS PROCESSES MANAGED BURNING
AND DISPOSAL 23.62
2012 CALIFORNIA AREAWIDE MISCELLANEOUS PROCESSES COOKING 5.77
2012 CALIFORNIA AREAWIDE MISCELLANEOUS PROCESSES OTHER
(MISCELLANEOUS
PROCESSES)
1.88
2012 CALIFORNIA MOBILE ON-ROAD MOTOR VEHICLES LIGHT DUTY PASSENGER
(LDA) 157.77
2012 CALIFORNIA MOBILE ON-ROAD MOTOR VEHICLES LIGHT DUTY TRUCKS - 1
(LDT1) 47.21
2012 CALIFORNIA MOBILE ON-ROAD MOTOR VEHICLES LIGHT DUTY TRUCKS - 2
(LDT2) 68.61
2012 CALIFORNIA MOBILE ON-ROAD MOTOR VEHICLES MEDIUM DUTY TRUCKS
(MDV) 57.75
2012 CALIFORNIA MOBILE ON-ROAD MOTOR VEHICLES LIGHT HEAVY DUTY
GAS TRUCKS - 1
(LHDGT1)
19.59
2012 CALIFORNIA MOBILE ON-ROAD MOTOR VEHICLES
LIGHT HEAVY DUTY
GAS TRUCKS - 2 (LHDGT2)
2.22
2012 CALIFORNIA MOBILE ON-ROAD MOTOR VEHICLES MEDIUM HEAVY DUTY
GAS TRUCKS (MHDGT) 5.64
2012 CALIFORNIA MOBILE ON-ROAD MOTOR VEHICLES HEAVY HEAVY DUTY GAS TRUCKS (HHDGT)
1.3
2012 CALIFORNIA MOBILE ON-ROAD MOTOR VEHICLES
LIGHT HEAVY DUTY
DIESEL TRUCKS - 1 (LHDDT1)
2.82
2012 CALIFORNIA MOBILE ON-ROAD MOTOR VEHICLES
LIGHT HEAVY DUTY
DIESEL TRUCKS - 2
(LHDDT2)
0.74
2012 CALIFORNIA MOBILE ON-ROAD MOTOR VEHICLES
MEDIUM HEAVY DUTY
DIESEL TRUCKS
(MHDDT)
7.83
2012 CALIFORNIA MOBILE ON-ROAD MOTOR VEHICLES HEAVY HEAVY DUTY
DIESEL TRUCKS
(HHDDT)
27.33
2012 CALIFORNIA MOBILE ON-ROAD MOTOR VEHICLES MOTORCYCLES (MCY) 30.34
2012 CALIFORNIA MOBILE ON-ROAD MOTOR VEHICLES HEAVY DUTY DIESEL
URBAN BUSES (UBD) 2.82
2012 CALIFORNIA MOBILE ON-ROAD MOTOR VEHICLES HEAVY DUTY GAS
URBAN BUSES (UBG) 0.99
2012 CALIFORNIA MOBILE ON-ROAD MOTOR VEHICLES SCHOOL BUSES - GAS
(SBG) 0.51
76
2012 CALIFORNIA MOBILE ON-ROAD MOTOR VEHICLES SCHOOL BUSES - DIESEL
(SBD) 0.48
2012 CALIFORNIA MOBILE ON-ROAD MOTOR VEHICLES OTHER BUSES - GAS
(OBG) 0.6
2012 CALIFORNIA MOBILE ON-ROAD MOTOR VEHICLES OTHER BUSES - MOTOR COACH - DIESEL (OBC)
0.26
2012 CALIFORNIA MOBILE ON-ROAD MOTOR VEHICLES ALL OTHER BUSES -
DIESEL (OBD) 0.35
2012 CALIFORNIA MOBILE ON-ROAD MOTOR VEHICLES MOTOR HOMES (MH) 0.8
2012 CALIFORNIA MOBILE OTHER MOBILE SOURCES AIRCRAFT 25.95
2012 CALIFORNIA MOBILE OTHER MOBILE SOURCES TRAINS 5.94
2012 CALIFORNIA MOBILE OTHER MOBILE SOURCES SHIPS AND
COMMERCIAL BOATS 0.04
2012 CALIFORNIA MOBILE OTHER MOBILE SOURCES OCEAN GOING VESSELS 9.34
2012 CALIFORNIA MOBILE OTHER MOBILE SOURCES COMMERCIAL HARBOR
CRAFT 4.7
2012 CALIFORNIA MOBILE OTHER MOBILE SOURCES RECREATIONAL BOATS 94.62
2012 CALIFORNIA MOBILE OTHER MOBILE SOURCES OFF-ROAD
RECREATIONAL
VEHICLES
16.16
2012 CALIFORNIA MOBILE OTHER MOBILE SOURCES OFF-ROAD EQUIPMENT 119.55
2012 CALIFORNIA MOBILE OTHER MOBILE SOURCES FARM EQUIPMENT 18.63
2012 CALIFORNIA MOBILE OTHER MOBILE SOURCES FUEL STORAGE AND
HANDLING 17.76
77
B. USDA Grape Crush by Type and Activity for 2017 Wine Crush Season
TABLE 1: STATE TOTALS OF GRAPES FOR CRUSHING BY TYPE AND VARIETY,
WEIGHTED AVERAGE DEGREES BRIX, AND WEIGHTED AVERAGE DOLLARS PER TON, 2016-17
Type and Variety Total Tons Crushed
Avg. Brix
Crushed Total Purchased Tons
Avg. Brix
Purchased
Wtd. Avg. Dollars
Per Ton
2017 2016 2017 2016 2017 2016 2017 2016 2017 2016
WINE GRAPES (WHITE):
Albarino 2,143.7 2,111.5 22.3 22.8 1,756.5 1,651.2 22.2 22.6 1108.91 1157.96
Arneis 111.8 175.0 23.1 23.0 81.4 111.9 23.6 23.1 2,126.91 1,939.00
Burger * 25,004.3 26,067.7 17.4 17.4 24,802.3 25,901.2 17.4 17.4 267.84 266.79
Chardonnay * 614,565.4 675,966.1 23.5 23.7 459,110.8 516,970.3 23.5 23.5 923.67 886.65
Chenin Blanc 35,565.7 42,555.7 20.4 20.6 32,660.4 39,667.8 20.4 20.6 405.86 383.29
Cortese 75.6 71.7 21.6 21.8 63.0 69.5 21.2 21.9 713.62 712.40
Fiano 66.0 52.8 22.6 22.5 35.0 27.4 22.0 22.2 1,802.30 1,582.46
Flora 27.7 33.6 22.1 22.4 24.0 28.8 21.9 22.1 2,113.71 2,031.13
Folle Blanche 0.0 18.7 0.0 23.6 0.0 0.0 0.0 0.0 0.00 0.00
French Colombard 335,762.3 303,480.0 19.9 20.6 327,265.3 294,717.4 19.9 20.5 267.39 260.92
Gewurztraminer 16,874.6 18,097.3 22.3 22.4 15,287.6 15,947.6 22.1 22.3 713.07 716.53
Gray Riesling * 96.0 87.4 21.9 23.1 89.2 87.4 21.4 22.2 1,764.66 1,534.01
Grenache Blanc 1,921.6 1,427.5 22.4 22.7 1,344.1 888.2 22.2 22.9 1,471.74 1,778.65
Gruner Veltliner 697.0 637.4 22.6 23.6 530.7 431.7 22.4 23.3 1,227.38 1,281.13
Malvasia Bianca 6,068.7 6,215.7 21.5 22.0 3,470.8 3,596.4 22.1 22.9 614.40 637.21
Marsanne 478.8 394.6 23.4 23.7 233.8 247.0 23.8 24.0 1,774.73 1,878.72
Melon 32.5 20.6 21.3 23.0 32.3 13.9 21.3 24.2 2,239.45 2,052.14
Moscato Gaillo * 16.7 12.4 21.7 22.9 5.4 2.7 22.9 22.4 1,477.78 1,355.56
78
Muscat Blanc * 27,186.0 26,369.3 22.9 23.3 22,887.7 22,087.1 23.0 23.6 481.32 439.78
Muscat Orange 3,263.4 3,789.6 23.8 23.6 2,622.2 3,039.1 23.6 23.8 564.54 542.64
Muscat of Alexandria 203,941.7 170,431.3 20.9 21.7 176,816.6 150,135.8 20.9 21.8 281.63 281.80
Palomino * 662.1 699.9 19.7 20.2 648.1 682.4 19.6 20.2 353.89 301.05
Pecorino 24.0 21.2 23.5 24.0 24.0 21.2 23.5 24.0 2,300.00 2,200.00
Picpoul Blanc 155.6 117.4 22.2 22.1 84.5 64.1 22.2 21.7 2,140.03 2,014.13
Pinot Blanc 1,299.6 1,417.0 23.6 23.5 867.2 929.8 23.8 24.2 1,571.94 1,469.36
Pinot Gris * 252,440.2 243,742.0 21.7 21.6 234,307.9 223,357.3 21.8 21.6 518.97 521.12
Ribolla Gialla * 41.0 41.3 20.6 20.9 35.3 37.4 20.4 20.9 3,299.70 3,092.92
Roussanne 1,237.2 1,143.6 23.2 23.8 589.3 595.3 23.5 24.2 2,063.66 1,999.13
Sauvignon Blanc 106,637.6 107,734.4 22.4 22.3 77,411.0 80,801.4 22.1 22.0 1,067.69 1,032.18
Sauvignon Gris 24.0 0.0 23.5 0.0 0.0 0.0 0.0 0.0 0.00 0.00
Sauvignon Musque 1,070.3 1,025.2 24.0 23.6 654.1 592.7 24.3 23.6 1,616.28 1,581.83
Sauvignon Vert * 23.6 18.8 22.3 23.4 23.6 18.8 23.1 23.4 2,580.27 2,549.88
Semillon 4,293.5 4,100.4 19.1 19.4 3,135.5 2,942.6 18.2 18.3 836.45 845.76
St. Emilion * 23.3 47.2 21.4 21.0 10.0 9.4 20.4 19.0 2,121.00 2,229.79
Sylvaner 18.6 36.9 20.5 20.5 0.0 0.0 0.0 0.0 0.00 0.00
Symphony 35,993.9 24,737.1 19.8 21.3 15,086.4 10,995.2 21.2 21.9 300.60 320.29
Tocai Friulano 60.9 75.4 22.2 22.2 42.5 47.8 21.3 21.8 1,929.71 1,952.83
Torrontes 32.3 40.1 21.9 22.1 29.9 32.3 22.4 22.1 1,420.07 1,346.13
Triplett Blanc 14,117.5 13,833.0 21.7 21.5 14,031.8 13,754.4 21.7 21.5 211.81 201.58
Verdejo 139.0 71.8 23.0 22.2 26.3 57.3 23.4 22.1 1,506.27 1,234.73
Verdelho 3,175.9 3,240.0 23.0 23.1 2,956.5 2,978.9 22.9 23.0 589.29 583.36
Vermentino * 1,047.9 1,307.3 21.7 20.1 833.2 1,069.8 21.7 19.8 1,015.65 824.48
Vernaccia 9.9 26.1 23.8 24.4 9.9 26.1 23.8 24.4 2,266.67 2,089.56
Viognier 19,812.8 22,698.0 25.0 25.5 16,309.7 18,702.0 25.0 25.6 695.71 659.67
White Riesling * 37,257.0 41,274.8 20.9 21.4 17,165.0 24,108.2 22.0 21.8 738.63 667.60
79
Other White 1/ 11,926.8 5,951.0 21.0 22.2 11,741.7 4,751.2 20.9 22.1 278.31 268.05
Total White 1,765,424.0 1,751,415.8 21.8 22.3 1,465,142.5 1,462,198.0 21.7 22.1 587.73 598.44
WINE GRAPES (RED):
Aglianico 188.8 142.9 24.4 24.1 106.8 81.7 24.5 23.4 1,639.03 1,567.09
Aleatico 23.5 26.9 25.5 24.6 21.9 23.2 25.9 24.7 2,738.29 2,653.53
Alicante Bouschet * 5,388.8 6,327.7 23.4 23.1 3,243.9 3,876.9 23.0 22.9 451.45 504.46
Alvarinho 0.5 0.0 23.0 0.0 0.0 0.0 0.0 0.0 0.00 0.00
Arinarnoa 3,297.9 3,496.0 23.9 24.3 3,297.7 3,495.5 23.9 24.3 385.13 350.00
Barbera 43,405.4 45,750.1 23.8 23.3 41,808.8 44,514.8 23.8 23.2 378.94 368.49
Blaufraenkisch * 16.3 20.1 24.9 23.3 10.8 10.2 24.2 22.4 1,473.91 1,810.78
Cabernet Franc 11,238.3 10,472.2 25.6 25.8 7,478.3 6,441.1 25.8 25.7 2,794.28 2,705.44
Cabernet Sauvignon 601,472.9 566,486.7 25.1 25.1 468,760.9 441,540.7 25.1 25.1 1,552.83 1,470.48
Carignane 12,112.7 14,397.1 22.7 22.4 11,741.9 14,018.4 22.7 22.3 506.62 473.06
Carmenere 50.4 48.5 24.9 24.8 23.4 27.2 25.2 25.1 2,572.82 1,684.99
Carnelian 889.9 2,474.9 27.0 24.8 865.2 2,461.9 27.1 24.8 250.00 249.29
Centurian 1,460.6 986.2 22.9 24.3 1,457.2 982.8 22.9 24.3 358.96 386.13
Charbono 292.0 313.8 23.4 23.7 180.6 213.0 23.6 24.0 2,685.69 2,613.21
Ciliegiolo 5.7 10.7 24.6 24.5 5.7 9.5 24.6 24.1 1,340.35 1,297.37
Cinsaut * 441.1 501.7 22.7 23.3 323.0 362.7 22.5 23.0 1,677.02 1,615.18
Counoise 213.7 193.2 23.2 22.9 137.0 119.8 23.5 22.9 1,879.29 1,813.24
Dolcetto 243.4 380.2 23.5 23.9 193.4 297.1 23.5 23.7 1,456.64 1,513.38
Dornfelder 1,791.8 1,531.5 22.2 23.1 914.9 887.6 22.5 22.8 440.51 422.20
Durif 31.4 33.9 25.5 24.8 1.1 1.2 24.3 23.9 1,450.00 1,450.00
Freisa 17.0 15.6 25.3 26.8 4.9 5.8 25.4 25.4 1,734.69 963.36
Gamay (Napa) * 1,836.3 1,704.3 21.7 21.8 1,568.7 1,359.7 21.4 21.6 980.43 858.55
80
Gamay Noir Au Jus
Blanc 43.3 35.9 21.9 21.2 43.3 31.7 22.0 21.3 2,393.76 2,057.10
Graciano 324.2 296.8 25.4 25.2 213.3 209.7 25.5 25.3 993.74 916.60
Grenache * 37,999.8 38,684.4 22.7 22.4 34,113.0 35,133.8 22.4 22.1 735.39 617.82
Grignolino 41.9 51.9 22.7 23.2 0.0 0.6 0.0 23.5 0.00 1,500.00
Lagrein 462.5 451.1 25.4 25.0 137.1 155.9 26.1 25.8 2,412.80 2,008.21
Lambrusco 260.9 257.6 25.6 25.0 0.0 0.0 0.0 0.0 0.00 0.00
Malbec 33,804.6 37,058.5 24.1 24.2 26,578.4 28,113.9 24.1 24.1 988.53 1,007.96
Merlot 255,195.8 268,761.6 25.0 25.2 201,472.5 214,647.7 24.9 25.1 770.26 774.91
Meunier * 878.3 785.2 20.0 20.4 452.1 357.8 20.2 20.3 2,200.11 2,099.82
Mission 994.8 2,422.0 23.7 21.7 976.2 2,383.7 23.7 21.7 289.37 219.84
Monastrell 25.5 19.3 26.7 26.1 12.9 6.0 26.1 27.3 2,261.58 2,003.33
Montepulciano 517.3 573.5 23.9 23.3 195.9 274.9 24.8 25.2 1,867.20 1,484.44
Mourvedre * 4,069.6 4,614.5 24.3 24.4 2,926.5 3,619.2 24.3 24.3 1,700.06 1,619.61
Muscat Hamburg * 1,181.7 612.5 24.8 25.3 1,155.8 563.0 24.8 25.3 689.58 630.86
Nebbiolo 466.8 511.7 24.3 24.4 305.4 401.1 24.6 24.7 1,432.37 1,184.74
Negrette * 14.5 29.1 25.6 25.6 0.5 19.2 25.0 25.8 2,250.00 1,928.91
Negroamaro 108.6 73.0 25.5 25.9 96.7 67.2 25.7 25.9 1,247.63 1,183.84
Nero D'Avola * 102.0 73.7 23.8 24.3 82.3 54.9 24.0 24.2 1,261.54 1,134.15
Petit Verdot 35,317.4 32,087.4 25.5 25.3 26,983.7 23,743.9 25.5 25.4 1,142.87 1,242.09
Petite Sirah 97,608.0 105,041.8 25.7 25.5 81,261.3 85,359.3 25.7 25.6 1,000.03 1,024.24
Pinot Noir 263,464.3 254,192.0 24.7 24.9 193,278.4 186,316.0 24.8 24.9 1,688.14 1,638.11
Pinotage 86.4 76.6 25.3 25.4 33.6 29.6 26.0 25.7 1,399.38 1,458.17
Primitivo 2,131.4 1,783.2 25.3 25.9 814.6 975.6 25.8 26.1 1,694.73 1,580.09
Refosco * 470.8 533.0 22.6 23.5 449.5 518.2 22.6 23.5 456.95 356.52
Royalty 33.0 31.3 25.3 24.7 33.0 31.3 25.3 23.0 475.00 475.00
Rubired * 239,625.0 247,539.2 24.1 24.3 228,760.9 238,827.2 24.1 24.4 276.95 279.28
Ruby Cabernet 59,505.2 54,733.6 24.5 24.7 58,907.2 54,326.1 24.6 24.7 301.10 304.18
81
Sagrantino 59.8 53.4 25.4 25.4 37.4 28.8 25.6 24.9 1,170.88 884.98
Salvador 327.9 448.1 25.4 23.0 327.9 448.1 25.4 23.0 291.47 301.29
Sangiovese * 6,360.6 6,399.4 23.4 24.3 3,954.4 3,976.6 23.5 24.0 1,308.08 1,187.20
Segalin 1,290.2 1,107.5 23.5 24.3 1,289.4 1,106.4 23.5 24.3 350.00 300.00
Souzao 637.6 554.2 25.0 25.1 553.3 445.4 24.9 25.1 605.03 727.66
St Laurent 26.2 34.5 19.7 20.9 18.0 18.4 19.5 19.7 2,296.67 2,256.52
Syrah * 100,714.4 108,406.6 24.9 25.5 78,897.5 84,172.1 24.8 25.4 810.98 785.61
Tannat 6,434.0 6,239.2 26.2 26.3 4,614.8 4,221.0 26.6 26.2 656.73 666.61
Tempranillo * 12,369.6 12,409.7 23.9 23.3 10,581.1 10,782.7 23.9 23.0 621.99 600.68
Teroldego 11,541.0 7,964.3 24.9 25.7 8,113.6 5,211.3 24.9 25.6 636.07 795.07
Tinta Cao 449.4 485.1 24.0 24.0 418.0 450.0 23.9 24.0 516.03 572.61
Tinta Madeira 58.2 91.8 24.9 26.7 0.8 32.7 25.0 27.1 1,284.54 712.69
Touriga Nacional * 4,226.1 2,485.9 24.1 24.4 4,051.8 2,309.0 24.1 24.3 554.88 706.37
Trousseau * 53.3 75.3 22.2 22.7 33.8 54.8 22.1 23.0 2,587.13 1,080.29
Zinfandel 364,833.9 416,648.0 22.2 22.1 337,916.6 395,278.1 22.1 21.9 591.05 604.62
Other Red 1/ 19,725.3 10,107.7 23.0 22.3 18,561.6 9,092.8 23.0 22.2 259.83 355.38
Total Red 2,248,259.5 2,280,155.3 24.3 24.3 1,870,800.2 1,914,526.5 24.2 24.2 965.54 919.04
TOTAL WINE 4,013,683.5 4,031,571.1 23.2 23.4 3,335,942.7 3,376,724.5 23.1 23.3 799.60 780.21
82
C. Measured GC Abundance and Calculated Indoor Concentrations of Ethanol and Benzene
October 16, 2018
GC Abundance Corresponding Air
Concentration (g/m3) Average Ethanol Conc (g/m3)
Std Dev Std. Error Average Benzene Conc (g/m3) Std Dev Error Ethanol Benzene Ethanol Benzene
Method Blanks
M01 1.75E+05 3.94E+04 2.30E-05 5.74E-06 1.42E-05 1.13E-05
M02 4.92E+04 8.64E+04 5.50E-06 1.69E-05
Trip
Blanks
T01 1.58E+05 2.65E+05 2.06E-05 5.90E-05 6.58E-05 3.61E-05
T02 8.06E+05 7.08E+04 1.11E-04 1.32E-05
Pump 1
F01 7.20E+05 1.89E+05 9.89E-05 4.10E-05
AS01 1.46E+08 4.36E+05 2.32E-02 9.96E-05
9.61E-03 1.10E-02 2.76E-03 1.14E-04 1.36E-04 3.40E-05 AS05 1.37E+07 6.38E+05 1.00E-03 1.47E-04
AS06 2.01E+06 2.73E+05 2.78E-04 6.10E-05
AS07 9.12E+07 8.30E+05 1.40E-02 1.93E-04
Pump 2
F02 5.39E+05 1.17E+05 7.38E-05 2.40E-05
AS02 8.36E+07 1.91E+05 1.27E-02 4.16E-05
4.28E-03 5.33E-03 1.07E-03 7.52E-05 7.68E-05 1.54E-05
AS03 2.56E+07 7.65E+04 3.01E-03 1.45E-05
AS08 1.52E+07 8.24E+05 1.26E-03 1.91E-04
AS09 1.30E+06 4.33E+05 1.80E-04 9.87E-05
AS11 5.13E+05 3.89E+04 7.01E-05 5.60E-06
Pump 3
AS04 3.20E+08 1.19E+06 5.25E-02 2.77E-04
1.14E-02 2.30E-02 4.59E-03 8.89E-05 1.02E-04 2.04E-05
AS10 3.54E+06 1.19E+05 4.92E-04 2.45E-05
AS12 1.79E+07 4.24E+05 1.70E-03 9.67E-05
AS13 2.29E+07 2.44E+05 2.55E-03 5.41E-05
AS14 2.89E+05 2.20E+05 3.89E-05 4.86E-05
83
November 16, 2018
GC Abundance
Corresponding Air
Concentration (g/m3)
Ethanol Benzene Ethanol Benzene
Average
Ethanol Conc
(g/m3) Std Dev Std. Error
Average Benzene
Conc (g/m3) Std Dev Error
Method
Blanks
M01 3.83E+05 1.58E+05 5.20E-05 3.39E-05 4.61E-05
2.50E-05
M02 2.98E+05 8.29E+04 4.02E-05 1.60E-05
Trip
Blanks
T01 3.47E+05 7.62E+04 4.70E-05 1.44E-05 4.10E-05 3.34E-05
T02 2.62E+05 2.37E+05 3.51E-05 5.24E-05
Pump 4
F02 9.53E+04 8.94E+04 1.19E-05 1.76E-05
AS02 7.52E+05 2.66E+05 1.03E-04 5.94E-05
1.94E-05 3.49E-05 1.16E-05 3.30E-05 1.29E-05 4.31E-06 AS06 2.58E+05 2.03E+05 3.45E-05 4.44E-05
AS11 4.30E+05 3.12E+05 5.85E-05 7.02E-05
Pump 3
AS08 4.59E+06 8.14E+05 6.37E-04 1.89E-04
4.20E-04 3.18E-04 7.95E-05 8.29E-05 5.59E-05 1.40E-05 AS09 5.60E+06 4.02E+05 7.79E-04 9.16E-05
AS10 2.85E+06 3.97E+05 3.95E-04 9.02E-05
AS13 3.88E+05 2.71E+05 5.27E-05 6.06E-05
Pump 1
F01 2.38E+05 9.39E+04 3.18E-05 1.86E-05
AS03 9.65E+06 5.13E+05 3.20E-04 1.18E-04
6.15E-04 2.97E-04 9.89E-05 8.38E-05 3.83E-05 1.28E-05 AS12 5.84E+06 2.97E+05 8.12E-04 6.67E-05
AS14 6.13E+06 6.15E+05 8.53E-04 1.42E-04
Pump 2
AS01 3.35E+06 6.56E+04 4.66E-04 1.19E-05
3.81E-04 2.46E-04 6.16E-05 1.69E-05 3.77E-05 9.43E-06 AS04 2.56E+06 1.21E+05 3.56E-04 2.50E-05
AS05 1.21E+07 4.25E+05 7.39E-04 9.69E-05
AS07 8.62E+06 1.58E+05 1.47E-04 3.38E-05
84
November 19, 2018
GC Abundance
Corresponding Air Concentration (g/m3)
Ethanol Benzene Ethanol Benzene
Average Ethanol
Conc (g/m3) Std Dev Std. Error
Average Benzene Conc
(g/m3) Std Dev Error
Method
Blanks
M01 8.84E+05 1.50E+05 1.22E-04 3.20E-05 6.44E-05
2.32E-05
M02 5.98E+04 7.64E+04 6.98E-06 1.45E-05
Trip Blanks
T01 7.07E+04 7.11E+04 8.50E-06 1.32E-05 9.01E-06 1.60E-05
T02 7.80E+04 9.45E+04 9.52E-06 1.88E-05
Pump 4
AS01 GC Fault
4.88E-04 6.14E-05 3.07E-05 1.73E-04 1.35E-05 6.77E-06 AS12 3.83E+06 8.02E+05 5.32E-04 1.86E-04
AS04 3.20E+06 8.83E+05 4.45E-04 2.05E-04
Pump 3
AS06 1.44E+08 5.84E+05 2.29E-02 1.34E-04
2.37E-02 1.78E-02 4.46E-03 1.28E-04 7.94E-05 1.98E-05 AS09 1.75E+08 9.48E+05 2.81E-02 2.21E-04
AS11 2.44E+06 2.13E+05 3.39E-04 4.67E-05
AS13 2.66E+08 8.82E+05 4.34E-02 2.05E-04
Pump 1
AS05 5.09E+06 8.56E+05 7.07E-04 1.99E-04
1.23E-02 1.90E-02 4.75E-03 1.53E-04 5.34E-05 1.34E-05 AS10 2.12E+08 9.20E+05 3.43E-02 2.14E-04
AS14 1.99E+07 5.01E+05 2.05E-03 1.15E-04
Pump 2
F01 1.70E+05 6.33E+04 2.23E-05 1.14E-05
F02 1.34E+06 1.47E+05 1.85E-04 3.12E-05
AS02 8.38E+06 6.83E+05 1.07E-04 1.58E-04
1.24E-02 1.48E-02 3.69E-03 9.28E-05 3.25E-05 8.12E-06 AS03 1.85E+08 4.56E+05 2.98E-02 1.04E-04
AS07 8.46E+06 3.57E+05 1.21E-04 8.08E-05
AS08 1.23E+08 5.27E+05 1.94E-02 1.21E-04
85
November 30, 2018
GC Abundance
Corresponding Air Concentration (g/m3)
Ethanol Benzene Ethanol Benzene
Average
Ethanol Conc
(g/m3) Std Dev Std. Error
Average Benzene Conc
(g/m3) Std Dev Error
Method
Blanks
M01 8.17E+04 1.21E+05 1.00E-05 2.51E-05 1.72E-05
2.27E-05
M02 1.84E+05 1.01E+05 2.43E-05 2.02E-05
Trip
Blanks
T01 nd nd 3.74E-05 1.10E-05
T02 2.78E+05 6.17E+04 3.74E-05 1.10E-05
Pump 4
F01 4.92E+05 4.57E+05 6.72E-05 1.05E-04
AS01 9.45E+05 3.22E+05 1.30E-04 7.25E-05
1.34E-04 9.09E-05 2.27E-05 1.13E-04 5.83E-05 1.46E-05 AS07 4.00E+05 8.67E+05 5.43E-05 2.01E-04
AS10 1.97E+06 7.15E+05 2.73E-04 1.66E-04
AS12 1.05E+06 7.88E+04 1.45E-04 1.51E-05
Pump 3
F02 3.43E+05 1.39E+05 4.65E-05 2.94E-05
AS04 4.39E+05 4.32E+05 5.97E-05 9.87E-05
5.88E-05 2.30E-05 5.75E-06 4.86E-05 3.88E-05 9.69E-06 AS09 6.72E+05 2.01E+05 9.23E-05 4.39E-05
AS14 GC Faults here
Pump 1
AS02 7.08E+05 3.12E+05 9.73E-05 7.02E-05
1.14E-04 4.80E-05 1.20E-05 3.77E-05 1.39E-05 3.47E-06 AS03 GC Faults here
AS05 GC Faults here
AS13 1.20E+06 2.29E+05 1.65E-04 5.06E-05
Pump 2
AS06 4.58E+05 3.56E+05 6.25E-05 8.06E-05
4.53E-05 5.80E-05 AS08 GC Faults here
AS11 GC Faults here
86
D. Ethanol and Benzene GCMS Calibration Points
Mass Ethanol Injected (µg) GC Abundance
394.50 589598572
157.80 254357370
31.56 60561135
6.31 12312027
1.26 2278306
0.25 441286
0.05 132658
0.01 23636
0.00 0
Mass Benzene Injected (µg) GC Abundance
1.00E+00 1067683
1.00E-01 164321
2.00E-02 38538
4.00E-03 7707
8.00E-04 1541
0.00E+00 0
87
E. AER Calculation Data
9/7/2018
CO2 1 (ppm) CO2 2 (ppm) Avg ln Avg CO2 time (min) Expected CO2 conc 627 627 6.440947 0.5
591 591 6.381816 1
583 583 6.368187 1.5
579 579 6.361302 2
567 567 6.340359 2.5
567 567 6.340359 3
559 559 6.326149 3.5
568 568 6.342121 4
598 598 6.393591 4.5
963 963 6.870053 5
1670 1670 7.420579 5.5
2755 2755 7.921173 6
3819 3819 8.247744 6.5
3967 3967 8.285765 7
3535 3535 8.170469 7.5
1964 3167 2565.5 7.849909 8
1904 2858 2381 7.775276 8.5
1870 2704 2287 7.734996 9
1896 2695 2295.5 7.738706 9.5
1755 2577 2166 7.680637 10
1428 2017 1722.5 7.451532 10.5
1149 1470 1309.5 7.177401 11
88
956 1154 1055 6.961296 11.5
822 1017 919.5 6.82383 12 920
816 953 884.5 6.785023 12.5 886
790 912 851 6.746412 13 855
752 906 829 6.72022 13.5 826
725 875 800 6.684612 14 800
724 867 795.5 6.678971 14.5 776
684 838 761 6.634633 15 754
682 794 738 6.603944 15.5 734
667 770 718.5 6.577166 16 715
636 765 700.5 6.551794 16.5 698
629 735 682 6.52503 17 682
633 714 673.5 6.512488 17.5 668
638 705 671.5 6.509514 18 654
605 680 642.5 6.465367 18.5 642
622 676 649 6.475433 19 631
614 656 635 6.453625 19.5 621
601 636 618.5 6.427297 20 611
581 647 614 6.419995 20.5 603
573 628 600.5 6.397763 21 595
573 615 594 6.386879 21.5 587
560 607 583.5 6.369044 22 581
568 596 582 6.36647 22.5 575
545 583 564 6.335054 23 569
547 582 564.5 6.33594 23.5 564
539 569 554 6.317165 24 559
541 563 552 6.313548 24.5 555
89
525 567 546 6.302619 25 550
504 556 530 6.272877 25.5 547
509 572 540.5 6.292495 26 543
532 566 549 6.308098 26.5 540
519 560 539.5 6.290643 27 537
507 552 529.5 6.271933 27.5 535
516 542 529 6.270988 28 532
509 540 524.5 6.262445 28.5 530
488 532 510 6.234411 29 528 519 519 6.251904 29.5 526
90
9/9/2019
CO2 1 CO2 2 Avg CO2 ln Avg Co2 time (min) Expected CO2 conc
774 651 712.5 6.47851 0.5
874 625 749.5 6.437752 1
820 613 716.5 6.418365 1.5
727 587 657 6.375025 2
647 590 618.5 6.380123 2.5
619 575 597 6.35437 3
614 565 589.5 6.336826 3.5
591 562 576.5 6.331502 4
591 548 569.5 6.306275 4.5
604 549 576.5 6.308098 5
602 549 575.5 6.308098 5.5
603 563 583 6.33328 6
592 565 578.5 6.336826 6.5
582 547 564.5 6.304449 7
582 553 567.5 6.315358 7.5
589 542 565.5 6.295266 8
561 538 549.5 6.287859 8.5
553 534 543.5 6.280396 9
569 543 556 6.297109 9.5
570 542 556 6.295266 10
554 538 546 6.287859 10.5
536 535 535.5 6.282267 11
535 512 523.5 6.238325 11.5
538 518 528 6.249975 12
91
550 516 533 6.246107 12.5
532 507 519.5 6.228511 13
520 515 517.5 6.244167 13.5
515 519 517 6.251904 14
517 506 511.5 6.226537 14.5
523 500 511.5 6.214608 15
531 509 520 6.232448 15.5
537 510 523.5 6.234411 16
539 503 521 6.22059 16.5
515 488 501.5 6.190315 17
511 491 501 6.196444 17.5
500 505 502.5 6.224558 18
504 504 504 6.222576 18.5
498 502 500 6.2186 19
505 499 502 6.212606 19.5
495 520 507.5 6.253829 20
502 520 511 6.253829 20.5
518 514 516 6.242223 21
607 541 574 6.293419 21.5
921 792 856.5 6.674561 22
1013 1038 1025.5 6.945051 22.5
1120 1428 1274 7.26403 23
1228 2290 1759 7.736307 23.5
1314 2652 1983 7.883069 24
1369 2745 2057 7.917536 24.5
1472 2788 2130 7.93308 25
1571 2999 2285 8.006034 25.5
92
1637 3178 2407.5 8.064007 26
1665 3208 2436.5 8.073403 26.5
1671 3158 2414.5 8.057694 27
1741 3070 2405.5 8.029433 27.5
1777 3085 2431 8.034307 28
1617 2998 2307.5 8.005701 28.5
1458 2852 2155 7.955776 29
1217 2771 1994 7.926964 29.5
1032 2627 1829.5 7.873598 30
893 2424 1658.5 7.793174 30.5
831 2091 1461 7.645398 31
766 1806 1286 7.49887 31.5
727 1533 1130 7.334982 32
737 1341 1039 7.201171 32.5
719 1208 963.5 7.096721 33 964
682 1118 900 7.019297 33.5 936
686 1066 876 6.971669 34 910
688 1041 864.5 6.947937 34.5 885
674 1028 851 6.93537 35 862
704 985 844.5 6.892642 35.5 840
675 983 829 6.890609 36 820
666 976 821 6.883463 36.5 801
650 956 803 6.862758 37 783
616 926 771 6.830874 37.5 766
622 905 763.5 6.807935 38 750
601 887 744 6.787845 38.5 736
589 866 727.5 6.763885 39 722
93
580 832 706 6.723832 39.5 708
588 795 691.5 6.678342 40 696
566 777 671.5 6.65544 40.5 685
554 775 664.5 6.652863 41 674
558 771 664.5 6.647688 41.5 663
569 737 653 6.602588 42 654
544 722 633 6.582025 42.5 645
539 700 619.5 6.55108 43 636
544 704 624 6.556778 43.5 628
532 685 608.5 6.529419 44 621
554 675 614.5 6.514713 44.5 614 669 669 6.505784 45 607
94
9/12/2018
CO2 1 CO2 2 Avg CO2 Ln Avg CO2 time (min) Expected CO2 conc
545 499 522 6.257668 0.5
528 535 531.5 6.275703 1
510 535 522.5 6.258625 1.5
486 519 502.5 6.219596 2
497 517 507 6.228511 2.5
506 500 503 6.22059 3
500 502 501 6.216606 3.5
481 495 488 6.190315 4
489 492 490.5 6.195425 4.5
476 497 486.5 6.187237 5
475 500 487.5 6.18929 5.5
470 476 473 6.159095 6
483 484 483.5 6.181051 6.5
476 477 476.5 6.166468 7
464 485 474.5 6.162262 7.5
467 472 469.5 6.151668 8
482 464 473 6.159095 8.5
475 464 469.5 6.151668 9
466 464 465 6.142037 9.5
461 476 468.5 6.149536 10
456 475 465.5 6.143112 10.5
449 463 456 6.122493 11
442 468 455 6.120297 11.5
457 468 462.5 6.136647 12
95
474 542 508 6.230481 12.5
662 748 705 6.558198 13
838 784 811 6.698268 13.5
917 859 888 6.788972 14
967 962 964.5 6.87161 14.5
1082 1043 1062.5 6.96838 15
1251 1234 1242.5 7.124881 15.5
1460 1419 1439.5 7.272051 16
1640 1683 1661.5 7.415476 16.5
1766 1845 1805.5 7.498593 17
1850 1905 1877.5 7.537696 17.5
1887 1787 1837 7.515889 18
1840 1741 1790.5 7.49025 18.5
1798 1685 1741.5 7.462502 19
1744 1669 1706.5 7.4422 19.5
1690 1621 1655.5 7.411858 20
1641 1596 1618.5 7.389255 20.5
1566 1561 1563.5 7.354682 21
1315 1400 1357.5 7.2134 21.5
1076 1170 1123 7.023759 22
926 992 959 6.865891 22.5
819 909 864 6.761573 23
768 831 799.5 6.683987 23.5 800
735 771 753 6.624065 24 772
702 752 727 6.588926 24.5 748
686 725 705.5 6.558907 25 725
672 687 679.5 6.521357 25.5 704
96
664 696 680 6.522093 26 685
642 688 665 6.499787 26.5 668
647 657 652 6.480045 27 652
649 655 652 6.480045 27.5 638
647 654 650.5 6.477741 28 625
628 647 637.5 6.457554 28.5 613
613 641 627 6.440947 29 602
608 626 617 6.424869 29.5 592
598 618 608 6.410175 30 582
582 603 592.5 6.384351 30.5 574
565 590 577.5 6.358708 31 566
562 596 579 6.361302 31.5 559
558 558 558 6.324359 32 553
553 561 557 6.322565 32.5 547
548 572 560 6.327937 33 542
533 573 553 6.315358 33.5 537
530 551 540.5 6.292495 34 532
533 522 527.5 6.268149 34.5 528
519 538 528.5 6.270043 35 524
523 531 527 6.267201 35.5 521 519
521
97
9/13/2019
CO2 1 CO2 2 Average CO2 ln Avg CO2 time (min) Expected CO2 conc
448 460 454 6.118097 0.5
460 454 457 6.124683 1
449 442 445.5 6.099197 1.5
431 465 448 6.104793 2
461 430 445.5 6.099197 2.5
462 435 448.5 6.105909 3
454 448 451 6.111467 3.5
431 442 436.5 6.078788 4
443 444 443.5 6.094698 4.5
446 443 444.5 6.09695 5
455 434 444.5 6.09695 5.5
465 455 460 6.131226 6
452 460 456 6.122493 6.5
451 478 464.5 6.140962 7
458 461 459.5 6.130139 7.5
451 443 447 6.102559 8
446 455 450.5 6.110358 8.5
453 456 454.5 6.119198 9
454 450 452 6.113682 9.5
456 458 457 6.124683 10
458 452 455 6.120297 10.5
463 448 455.5 6.121396 11
457 454 455.5 6.121396 11.5
475 464 469.5 6.151668 12
483 469 476 6.165418 12.5
98
481 455 468 6.148468 13
480 466 473 6.159095 13.5
475 491 483 6.180017 14
468 457 462.5 6.136647 14.5
470 460 465 6.142037 15
480 467 473.5 6.160152 15.5
463 449 456 6.122493 16
464 446 455 6.120297 16.5
450 438 444 6.095825 17
467 450 458.5 6.12796 17.5
457 454 455.5 6.121396 18
452 459 455.5 6.121396 18.5
456 443 449.5 6.108136 19
474 459 466.5 6.145258 19.5
490 461 475.5 6.164367 20
546 461 503.5 6.221584 20.5
605 487 546 6.302619 21
620 481 550.5 6.310827 21.5
602 474 538 6.287859 22
577 464 520.5 6.25479 22.5
590 489 539.5 6.290643 23
551 474 512.5 6.239301 23.5
517 541 529 6.270988 24
544 774 659 6.490724 24.5
671 1084 877.5 6.777077 25
862 1422 1142 7.040536 25.5
1055 1655 1355 7.211557 26
99
1322 1805 1563.5 7.354682 26.5
1735 2051 1893 7.545918 27
2095 2292 2193.5 7.693254 27.5
2213 2426 2319.5 7.749107 28
2244 2392 2318 7.74846 28.5
2300 2391 2345.5 7.760254 29
2243 2309 2276 7.730175 29.5
2231 2204 2217.5 7.704136 30
2208 2201 2204.5 7.698256 30.5
2163 2187 2175 7.684784 31
2119 2126 2122.5 7.66035 31.5
2078 2082 2080 7.640123 32
2030 2063 2046.5 7.623886 32.5
2017 1970 1993.5 7.597647 33
2010 1982 1996 7.5989 33.5
1955 1882 1918.5 7.559299 34
1736 1752 1744 7.463937 34.5
1433 1629 1531 7.333676 35
1251 1508 1379.5 7.229476 35.5
1149 1415 1282 7.156177 36
1073 1281 1177 7.070724 36.5
985 1191 1088 6.992096 37
940 1061 1000.5 6.908255 37.5
879 1013 946 6.852243 38
854 985 919.5 6.82383 38.5 920
817 941 879 6.778785 39 894
804 925 864.5 6.762151 39.5 869
100
803 878 840.5 6.733997 40 846
782 867 824.5 6.714777 40.5 824
768 849 808.5 6.695181 41 804
753 826 789.5 6.6714 41.5 784
728 808 768 6.64379 42 766
725 771 748 6.617403 42.5 749
699 762 730.5 6.593729 43 732
694 747 720.5 6.579945 43.5 717
674 719 696.5 6.546068 44 702
656 719 687.5 6.533062 44.5 689
634 731 682.5 6.525763 45 676
628 703 665.5 6.500539 45.5 663
633 682 657.5 6.488445 46 652
607 684 645.5 6.470025 46.5 641
598 651 624.5 6.436951 47 631
591 649 620 6.429719 47.5 621
578 649 613.5 6.41918 48 612
570 648 609 6.411818 48.5 603
563 607 585 6.371612 49 595
567 637 602 6.400257 49.5 587
561 623 592 6.383507 50 580
536 607 571.5 6.348264 50.5 573
527 611 569 6.34388 51 566
518 587 552.5 6.314453 51.5 560
519 563 541 6.293419 52 554
524 587 555.5 6.319869 52.5 549
514 589 551.5 6.312642 53 544
101
505 551 528 6.269096 53.5 539
507 544 525.5 6.26435 54
486 542 514 6.242223 54.5
488 545 516.5 6.247075 55
491 532 511.5 6.237348 55.5
490 525 507.5 6.229497 56
489 523 506 6.226537 56.5
487 510 498.5 6.211604 57
477 523 500 6.214608 57.5
476 523 499.5 6.213608 58
466 511 488.5 6.191339 58.5
462 505 483.5 6.181051 59
466 521 493.5 6.201523 59.5
456 491 473.5 6.160152 60